This application is a U.S. National stage application of International Application No. PCT/JP2010/062570, filed Jul. 27, 2010, which claims priority claims priority under 35 U.S.C. §119(a) to Japanese Patent Application No. 2009-174310, filed in Japan on Jul. 27, 2009, the entire contents of which is hereby incorporated by reference.
The present invention relates to a window regulator in which a tilted structure is provided on a carrier plate or a stopper member.
For some time, window regulators have generally been used in vehicles to raise and lower a window pane. A window regulator comprises: a guide rail that extends along a movement direction of a window pane; a drive section attached to a lower end of the guide rail; a drum that is rotated by a torque received from the drive unit; a carrier plate that is slidably mounted on the guide rail and serves to support the window pane; two power transmitting members each having one end connected to the drum and another end connected to the carrier plate; and a guide and pulley that are attached to an upper end of the guide rail and serve to change an arrangement direction of one of the power transmitting members.
Vehicle doors can be roughly divided into types that have a sash for regulating an upper end position of the window pane and types that do not have a sash. The method of regulating the upper end position of the window pane is different for each type. In a door having a sash, the upper end position of the window pane is regulated by the window pane contacting an upper portion of the sash. In a door not having a sash, the upper end position of the window pane is regulated by the carrier plate contacting a stopper member provided on the guide rail or other portion. When the carrier plate contacts the stopper member, the motor is restrained and a large electric current flows, resulting in a possibility that the motor and/or a control board of the motor will be damaged by heat. Therefore, a circuit breaker or a PTC thermistor is provided on the control board to shut off electric power to the motor and stop the motor when a large electric current flows.
When contact of a carrier plate against a stopper member provided on a guide rail or the like is used as the regulating method, an impact absorption body made of rubber or another elastic material is provided in-between to absorb the impact occured at the time of contact.
For example, Laid-Open Japanese Utility Model Application Publication No. 63-132080 (Patent Document 1) discloses a window regulator having a damping member and a carrier plate. The damping member comprises a damping main body fitted into a wire guide member provided on a lower end portion of a guide rail and a mounting leg section that engages with an engaging hole of the guide rail. The carrier plate is provided with a contact member that contacts the damping member.
Laid-Open Japanese Patent Application Publication No. 2002-129831 (Patent Document 2) discloses a window regulator having a damping member and a carrier plate. The damping member comprises a circular arc-shaped contact section and an insertion section. The contact section is assembled with a cable guide provided on a lower end portion of a guide rail and contacts the carrier plate, and the insertion section has a narrower width than the contact section. The carrier plate has a contact section that contacts the damping member.
With the window regulators presented in Patent Document 1 and Patent Document 2, when the carrier plate sliding along the guide rail contacts the stopper member in a tilted state, a force acts on the carrier plate in a direction of derailing the carrier plate from the guide rail and causes the carrier plate to derail from the guide rail.
As shown in
In such a case, as shown in
Since it is possible for the carrier plate 400 to move rightward in this state, a motor drive circuit will continue powering the motor. Therefore the force applied at the force applying point P will cause the carrier plate 400 to rotate in the direction of the arrow L such that the carrier plate 400 lifts up from the guide rail 420. Thus, the carrier plate 400 will be in the state shown in
The phenomenon of the carrier plate lifting from and derailing from a guide rail occurs after an impact absorbing body provided on the carrier plate contacts the stopper member or an impact absorbing body provided on the stopper member contacts the carrier plate. The disclosed window regulator is intended to provide a structure of a carrier plate or a stopper member that serves to solve the phenomenon.
A disclosed window regulator is configured to open and close a window pane and comprises a guide rail, a carrier plate, and a stopper member. The guide rail is fixed to a door of a vehicle. The carrier plate is slidably attached to the guide rail and comprises a guide rail fitting section that fits together with the guide rail. A window pane fastening section and a connecting section that connects to a power transmitting means for transmitting power generated by a drive section. The stopper member regulates a slide position of the carrier plate. An impact absorbing body made of an elastic material is attached to one of the carrier plate and the stopper member, and a collision surface for colliding with the impact absorbing body is formed on the other of the stopper member and the carrier plate. The collision surface has such a shape that it pushes the carrier plate down toward the guide rail when it collides with the impact absorbing body.
(1) In the disclosed window regulator, an impact absorbing body made of an elastic material is attached to the carrier plate and a collision surface for colliding with the impact absorbing body is formed on the stopper member, or an impact absorbing body made of an elastic material is attached to the stopper member and a collision surface for colliding with the impact absorbing body is formed on the carrier plate. Additionally, the collision surface has such a shape that the carrier plate is pushed down toward the guide rail when it collides with the impact absorbing body. As a result, even if the impact absorbing body collides with the collision surface, a force acting in a direction of derailing the carrier plate from the guide rail can be prevented from acting on the carrier plate.
(2) If the collision surface is tilted so as to form an acute angle with respect to the guide rail, then the tilted surface can prevent a force from acting on the carrier plate in a direction of derailing from the guide rail.
(3) If an opposing surface that faces opposite the collision surface is formed on either the carrier plate or the stopper member and is parallel to the collision surface, then a force can be prevented from acting on the carrier plate in a direction of derailing the carrier plate from the guide rail when the collision surface and the opposing surface contact each other.
(4) If the opposing surface has a recess for attaching the impact absorbing body, then the impact absorbing body can be reliably supported in the recess.
(5) If the stopper member is provided as an integral unit with a housing of the drive section, then the number of parts making up the window regulator can be reduced and a stiffness of the stopper member can be increased.
Referring now to the attached drawings which form a part of this original disclosure.
A window regulator according to the present invention will now be explained in detail with reference to the appended drawings.
The window regulator 20 according to this embodiment will now be explained with reference to
The carrier plate 1 is connected to the guide rail 6 by the guide rail fitting section 7 and is fitted such that it can be slid up and down the guide rail 6 by power generated by the drive section 9. The drive section 9 is equipped with an electric motor and has a recess in which a rotary drum (not shown in the drawings) is rotatably housed. One end of each of the wires 4a and 4b (which serve as a power transmitting means) is secured to the rotary drum. Power (e.g., rotary torque) generated by the electric motor is transmitted through a reduction gear mechanism to the rotary drum such that, for example, one wire 4a is wound in and the other wire 4b is reeled out. When this occurs, the carrier plate 1 moves along the guide rail 6 because the other ends of the wires 4a and 4b are secured to the carrier plate 1 by the cable ends Ca and Cb.
The carrier plate 1 can be formed as a one-piece integral unit made of a synthetic resin (e.g., such an engineering plastic as polyamide or polyacetal, or another synthetic resin having superior mechanical properties). It is also possible to fabricate the carrier plate 1 of separate entities fastened together by heat fusion, screw connections, or another fastening means. Also, the material of the carrier plate 1 is not limited to a synthetic resin; it is also acceptable to make the carrier plate 1 out of metal or a combination of metal and synthetic resin.
A window pane fastening section 8 for fastening a window pane is provided on the carrier plate 1, and the window pane fastening section 8 provided on the carrier plate 1 has a hole for inserting a bolt to fastening a vehicle window pane (not shown) to the carrier plate 1.
In this embodiment, the guide rail fitting section 7 is a claw configured to engage with a lengthwise side edge of the guide rail 6 (see
A stopper member 3 that restricts a lower end position of the carrier plate 1 is provided as an integral part of the drive section 9. When the window pane is lowered, the carrier plate 1 is stopped at a lower end position due to the carrier plate 1 contacting the stopper member 3. Since the stopper member 3 is provided as an integral unit with the drive section 9, the number of parts of the window regulator can be reduced and a force acting on the stopper member can be supported by the entire housing. Consequently, a stiffness of the stopper member can be increased.
An impact absorbing body 2 is provided on the carrier plate 1 to reduce an impact and emission of a hitting sound occurring when the carrier plate 1 and the stopper member 3 contact each other. The impact absorbing body 2 is installed in a press fitting recess 5 provided in the carrier plate 1. The impact absorbing body 2 can be reliably supported by installing it into the press fitting recess.
The impact absorbing body 2 is made of a chloroprene rubber or other elastic material having a generally column-like shape that is substantially rectangular. A damping section 21 is formed on a side of the impact absorbing body 2 that contacts the stopper member 3. In this embodiment, the damping section 21 is substantially shaped like a four-sided pyramid such that it narrows toward a tip end. Since the tip end is narrow, the stopper member 3 and impact absorbing body 2 do not undergo a surface-to-surface contact and, thus, emission of a hitting sound can be reduced.
Although in this embodiment the impact absorbing body has a generally rectangular shape, there are no particular limitations on the shape of the impact absorbing body 2 and a column-like body having substantially the shape of a circular column, a triangular column, a rectangular column, or a pentagonal column can be used. The shape of the press fitting recess 5 can also be changed as appropriate in accordance with the shape of the impact absorbing body 2.
Although in this embodiment the press fitting recess section 5 is formed in the carrier plate 1, it is also possible to form a press fitting recess section 5 in the stopper member 3 and not form a press fitting recess section 5 in the carrier plate 1.
A collision surface 11 of the stopper member 3 that collides with the impact absorbing body 2 is shaped such that the carrier plate 1 is pushed down toward the guide rail 6 when the impact absorbing body 2 collides against the collision surface 11. In the example shown in
As shown in
A force acting in a direction of derailing the carrier plate 1 from the guide rail 6 occurs when an angle α1 and an angle β1 between the collision surface 11 of the stopper member 3 and an axis B of the impact absorbing body 2 have the relationship α1>β1, as shown in
Additionally,
Thus, by providing a tilted surface on each of the carrier plate 1 and the stopper member 3, the carrier plate 1 can be prevented from separating from the guide rail 6 with a simple structure. Also, since a force does not acting in a direction of separating the carrier plate 1, there are no particular limitations on the shape of the impact absorbing body 2.
Although in this embodiment the impact absorbing body 2 is provided on the carrier plate 1, the principle is the same if the impact absorbing body 2 is provided on the stopper member 3 (see
Additionally, since the collision surface is a tilted surface in this embodiment, there are not limitations on the cross sectional shape, i.e., it is acceptable if the cross sectional shape is circular arc-shaped or U-shaped.
Number | Date | Country | Kind |
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2009-174310 | Jul 2009 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2010/062570 | 7/27/2010 | WO | 00 | 1/24/2012 |
Publishing Document | Publishing Date | Country | Kind |
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WO2011/013641 | 2/3/2011 | WO | A |
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Entry |
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International Search Report of corresponding PCT Application No. PCT/JP2010/062570. |
Number | Date | Country | |
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20120117883 A1 | May 2012 | US |