INSIDE HANDLE DEVICE FOR VEHICLE

Abstract

An inside handle device for a vehicle includes an operating handle which is connected to a handle base fixed to a door of a vehicle so as to be rotatably operable from an initial rotation position to an operation rotation position, and a torsion spring in which one arm portion extending from a coil portion is engaged with an engaging portion of the handle base and in which the other arm portion is engaged with an engaging portion of the operating handle, so as to urge the operating handle toward an initial rotation position side.

Claims

1. An inside handle device for a vehicle comprising: an operating handle which is connected to a handle base fixed to a door of a vehicle so as to be rotatably operable from an initial rotation position to an operation rotation position; and a torsion spring in which one arm portion extending from a coil portion is engaged with an engaging portion of the handle base and in which the other arm portion is engaged with an engaging portion of the operating handle, so as to urge the operating handle toward an initial rotation position side, wherein the torsion spring is mounted in a wound state that the coil portion moves away from or toward an engaged position of the one arm portion or an engaged position of the other arm portion in an entire stroke from a set state that the operating handle is in the initial rotation position to an operation state corresponding to the operation rotation position of the operating handle, and wherein the one arm portion or the other arm portion is constrained in a moving direction of the coil portion and is allowed to move in a direction opposite to the moving direction to be engaged with a corresponding portion.

2. The inside handle device for a vehicle according to claim 1, wherein an angle between the one arm portion and the other arm portion in the initial rotation position is set to be greater than a deflection angle in the operation state and the torsion spring is used, wherein each of the one arm portion and the other arm portion is formed in a straight rod shape, wherein a free end of the one arm portion abuts against an abutting wall formed in the handle base, and wherein a free end of the other arm portion abuts against an abutting wall formed in the operating handle.

3. The inside handle device for a vehicle according to claim 2, wherein the engaging portion of the handle base has an engaging wall with which the one arm portion is engaged as a back wall and the abutting wall which is formed in the handle base as a bottom wall, and wherein the engaging portion of the handle base has a pair of regulation walls, which protrudes from the engaging wall and regulates the movement of the one arm portion in a direction along the engaging wall, as a side wall and is formed in a bottomed cylindrical shape having a U-shaped cross section which is opened in a winding direction.

4. The inside handle device for a vehicle according to claim 1, wherein a pair of arm portions extending from the coil portion and including one arm portion and the other arm portion is formed to have the same length.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0022] FIG. 1 is a front view illustrating an inside handle device.

[0023] FIG. 2 is a sectional view that is taken along line 2A-2A of FIG. 1.

[0024] FIG. 3 is a sectional view that is taken along line 3A-3A of FIG. 1.

[0025] FIG. 4 is a sectional view that is taken along line 4A-4A of FIG. 1.

[0026] FIG. 5 is a sectional view that is taken along line 5A-5A of FIG. 1.

[0027] FIG. 6 is an explanatory perspective view illustrating a relationship between an operating handle and a torsion spring.

DETAILED DESCRIPTION

[0028] As illustrated in FIGS. 1 to 6, an inside handle device is formed by connecting an operating handle 2 and a lock knob 10 to a handle base 1 so as to be rotatable around a rotation center (C), and is fixed to a door of a vehicle in the handle base 1.

[0029] The operating handle 2 can be rotated from an initial rotation position illustrated in FIG. 2 to an operation rotation position rotated in a direction of an arrow (H) around a rotation shaft member 11 forming the rotation center (C). The operating handle 2 is operated to rotate to the operation rotation position and thereby a door locking device (not illustrated) within a door is operated via a transmission member 12 such as a cable device connected to a connecting portion 2a and a latch holding a closed state of the door is released.

[0030] In addition, the lock knob 10 is operated to be rotatable between a locked rotation position and an unlocked rotation position, and when the lock knob 10 is in the locked rotation, the door locking device connected to the lock knob 10 is in a locked state. Therefore, a latch releasing operation is prohibited by the operating handle 2 and the latch releasing operation is allowed by the operating handle 2 only when the lock knob 10 is in an unlocked state.

[0031] Moreover, in the example, a case where the connection of the operating handle 2 and the lock knob 10 to the handle base 1 is performed by using the rotation shaft member 11 installed on the handle base 1 is illustrated, but the connection of the operating handle 2 and the lock knob 10 to the handle base 1 can be performed, for example, by rotatably fitting the operating handle 2 and the lock knob 10 with a hinge projection formed in the handle base 1 without using the rotation shaft member 11.

[0032] A torsion spring 6 is mounted to urge the operating handle 2 in a direction of the initial rotation position to automatically return from the operation rotation position and to prevent rattling at the initial rotation position.

[0033] The torsion spring 6 is formed by extending straight rod-shaped arm portions 4 from both ends of a coil portion 3. The coil portion 3 is wound around the rotation shaft member 11 and the torsion spring 6 is mounted by engaging the arm portions 4 with engaging portions 5 formed in the operating handle 2 and the handle base 1 respectively.

[0034] As illustrated in FIGS. 2 and 3, each of the engaging portions 5 has an engaging wall 8 engaging with the arm portion 4 for applying a predetermined deflection angle to the coil portion 3 and is disposed at a position held in a deflected state (S state in FIG. 2) deflected by a deflection angle (0) from a free state (F state in FIG. 2) of no load.

[0035] In the example, two arm portions 4 are formed to have the same length and even when the torsion spring 6 is mounted in a reversed posture which is reversed with respect to a center line of the coil portion 3 in a width direction, a distance between a center of the coil portion 3 and a contact point of the arm portion 4 with an engaging wall 8 is considered to be unchanged.

[0036] In addition, each of the engaging portions 5 is provided with an abutting wall 7 that is a bottom wall in a case where an engaging wall 8 against which a free end of the arm portion 4 abuts in a mounting state is a back wall, and a pair of regulation walls 9 that is a side wall in a case where the engaging wall 8 is the back wall.

[0037] As illustrated in FIG. 4, the regulation wall 9 is formed as a wall surface on a handle base 1 side and, as illustrated in FIG. 6, one of the regulation walls 9 in the operating handle 2 is formed in a bar shape.

[0038] In addition, as illustrated in FIG. 4, an interval between the regulation walls 9 is formed to be slightly wider than a wire diameter of the arm portion 4 and the movement of the arm portion 4 in a direction along the engaging wall 8 is regulated in an engaged state between the regulation walls 9.

[0039] With the above configuration, the mounting of the torsion spring 6 is performed by pressing the arm portion 4 against an end surface of the abutting wall 7 in a state where the rotation shaft member 11 passes through the coil portion 3. The coil portion 3 is deformed in a winding direction by a pressing operation of the arm portion 4 due to a reaction force from the abutting wall 7 generated in the arm portion 4. As a result, after the arm portion 4 rides over the end surface of the abutting wall 7, the arm portion 4 is elastically fitted to the engaging portion 5 by an elastically restoring force of the coil portion 3.

[0040] As illustrated in FIG. 2, since two arm portions 4 are set to be in the non-intersecting state in which both the F state and the S state do not intersect with each other, a force in a direction of an arrow (F) in FIG. 2 is generated in the coil portion 3 in a state where the arm portion 4 is in pressed contact with the engaging wall 8. As a result, the free end of the arm portion 4 is in a state of being in pressed contact with the abutting wall 7 and the torsion spring 6 is held at the position.

[0041] Furthermore, the coil portion 3 of the torsion spring 6 is set such that even in a case where the operating handle 2 is operated to rotate to the operation rotation position and the deflection angle (1) is increased, the two arm portions 4 hold a non-intersecting posture. Therefore, a force in the direction of the continuous arrow (F) acts on the coil portion 3 and the torsion spring 6 is held at the initial position even by the rotational operation of the operating handle 2 to the operation rotation position.

[0042] This application is based on Japanese patent application (Japanese Patent Application No. 2015-096482) filed on May 11, 2015 and the contents of which are incorporated herein by reference.

REFERENCE SIGNS LIST

[0043] 1 handle base

[0044] 2 operating handle

[0045] 3 coil portion

[0046] 4 arm portion

[0047] 5 engaging portion

[0048] 6 torsion spring

[0049] 7 abutting wall

[0050] 8 engaging wall

[0051] 9 regulation wall