JP2009299429A - Tensioning mechanism of inner cable, and window regulator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a tensioning mechanism which can apply initial tension to an inner cable without directly touching a guide member, and a window regulator. <P>SOLUTION: A guide member 13 is rotatably mounted on a base 11 by a shaft 12, and a carrier plate 15 is locked to an inner cable 14 whose direction is changed by the guide member 13. A substantially U-shaped wiring path regulated by a guide channel 42 formed on an outer periphery of the guide member 13 and the part supporting the inner cable is short when the guide member is at a first rotation end, and the wiring path is longer than that when the guide member is at a second rotation end. The wiring path becomes longest when the guide member reaches a top dead center during its movement from the first rotation end to the second rotation end. An engaging member 16 engaging the guide member 13 is mounted on the carrier plate 15 to rotate the guide member 13 from the first rotation end to the second rotation end. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a mechanism for removing an initial slack after wiring of an inner cable and providing a predetermined tension, and a window regulator using the mechanism. More particularly, the present invention relates to a tension release mechanism and a window regulator for automatically taking out an initial slack by a reciprocating drive operation of the inner cable after the inner cable has been routed, and generating a tension.

JP 2006-34827 A

  Patent Document 1 discloses a window regulator 100 as shown in FIG. The window regulator 100 hangs in an 8-character shape between the cable guides 102, 103, 104, and 105 that are attached to the upper and lower front and rear (up and down and left and right) of an inner panel (not shown) of an automobile door. Looped (endless) inner cable 106, front carrier plate 107 locked between the front upper and lower cable guides 102 and 103 of the inner cable, and rear upper and lower cable guides 104 and 105 And a cable driving device 109 that reciprocates and drives the inner cable 106.

Further, in Patent Document 1, an inner cable slack preventing means 111 for attaching an end of an outer casing 110 for guiding an inner cable 106 to a cable driving device 109 via a spring, and a front and lower cable guide 103 are connected to an inner panel. An inner cable tensioning mechanism 113 configured to be fixed to a bracket 112 that is movably provided is disclosed. In the window regulator 100, the bracket 112 is made rotatable when assembled to the inner panel, and the bracket 11 resists the urging force of the spring of the locking means at the final stage of assembly.
2 is rotated in the counterclockwise direction (arrow R direction), and in this state, the bracket 112 is fixed to the correct position with the bolt 114. Thereby, the inner cable 106 can be loosened during assembly, and tension can be applied to the inner cable 106 at the end of assembly.

  The tensioning mechanism 113 of Patent Document 1 can apply tension to the inner cable 106 at the end of assembly, but the operator rotates the bracket 112 to the correct position against the biasing force of the spring, and in this state Since it is necessary to fix the bracket 113 with the bolt 114, the operation is complicated. In particular, the window regulator is provided between the inner panel and the outer panel, and is fixed to the inner panel 101. Therefore, it is more troublesome because the user puts a hand through the opening window 115 provided on the inner panel.

  An object of the present invention is to provide a tensioning mechanism that can apply tension to an inner cable without an operator directly touching a guide member or a bracket. Another object of the present invention is to provide a window regulator that can be easily assembled to an inner panel or a module panel.

  An inner cable tensioning mechanism of the present invention (Claim 1) is slidable in a guide member provided with a support member, a substantially arc-shaped guide groove attached to the support member, and the guide groove of the guide member. An inner cable that is engaged and changed in direction, and an operating member that is locked to the inner cable and is driven to reciprocate in the tension direction of the inner cable as the inner cable reciprocates, and the guide member supports the support The member is rotatably attached to the member between the first rotation end and the second rotation end, and the routing path passing through the guide groove at the second rotation end is the first rotation. It is configured to be longer than the routing path passing through the guide groove at the end, and when the operating member moves in a direction approaching the guide member, the guide member is engaged with the guide member to perform the first rotation. End An engagement piece that rotates to the second rotation end is provided, and a return preventing means that does not return to the first rotation end side after the guide member reaches the second rotation end is provided. It is characterized by that.

  In such a tensioning mechanism, the guide member is configured such that the routing path in the middle of the first rotating end and the second rotating end is longer than the routing path at the second rotating end. Accordingly, the return prevention means is preferable (claim 2).

  Furthermore, between the guide member and the support member, there is provided a lock means that engages with each other to prevent the guide member from returning when the guide member reaches the second rotation end. The return prevention means may be provided, or both of the two return prevention means may be provided (claim 3).

  Further, it is preferable that the change in the length of the routing path is caused by a smooth change in the distance from the rotation center of the guide member to the bottom of the guide groove (claim 4).

  The window regulator of the present invention (Claim 5) is stretched between an upper guide member and a lower guide member attached to the upper part and the lower part, respectively, and the upper and lower guide members, and the direction is changed by these guide members. An inner cable that is alternately pulled and pulled, a carrier plate (the aforementioned actuating member) that is locked to a region stretched between the upper and lower guide members of the inner cable, and the inner cable A window regulator comprising a cable drive device that reciprocally drives alternately, wherein any one of the tension-extraction mechanisms is used in at least one of the upper guide member and the lower guide member. .

  In such a window regulator, the support member may be a module panel attached to an inner panel of an automobile door, and the support member is attached to a module panel attached to an inner panel of an automobile door. The base member may be used.

  First, the inner cable is engaged with the guide groove in a state where the guide member is rotated to the first rotation end. In this state, since the routing route is short, the inner cable is slackened, and the assembly work of other guide members and the like is easy. At the final stage of assembly, the inner cable is operated to move the operating member to the guide member side. Thereby, the engaging piece of the operating member engages with the guide member and rotates to the second rotating end. Thereafter, the return preventing means does not return the guide member to the first rotation end side, so that the tension of the inner cable is maintained even when the operating member is separated from the guide member. After the assembly, the operating member can be reciprocated along the tension direction of the inner cable by reciprocating the inner cable.

  The guide member is configured such that a routing path in the middle of the first rotating end and the second rotating end is longer than a routing path at the second rotating end, whereby the return preventing means If the guide member is rotated to the second rotation end and tension is applied to the inner cable, the guide member is moved to the second rotation end side by the tension. Pressed. As a result, the guide member does not rotate to the first rotation end side unless the inner cable is excessively loosened or the guide member is forcibly rotated to the first rotation end side.

  Between the guide member and the support member, there is provided locking means that engages with each other and prevents the guide member from returning when the guide member reaches the second rotation end, and the locking means is In the case of the return prevention means (Claim 3), once the guide member is rotated to the second rotation end and tension is applied to the inner cable, the guide member is restrained by the locking means. Thereby, even if excessive looseness occurs in the inner cable, the guide member does not rotate to the first rotation end side.

  When the change in the length of the routing path is caused by a smooth change in the distance from the rotation center of the guide member to the bottom of the guide groove (Claim 4), the guide member The length of the routing path changes smoothly with the rotation.

  In the window regulator of the present invention (Claim 5), since any one of the above-described tension releasing mechanisms is used for at least one of the upper guide member and the lower guide member, tension is applied to the inner cable at the final stage of assembly. Can be granted. Therefore, the inner cable can be loosened in the middle of assembly, and the assembly work is easy. Further, in the case of a type of window regulator that is attached to the inner panel after the guide member is attached to the flexible module panel, the above-described tensioning operation can be performed after the module panel is attached to the inner panel.

  Next, an embodiment of a tensioning mechanism for an inner cable and a window regulator according to the present invention will be described with reference to the drawings. FIG. 1 is a front view showing an embodiment of a tensioning mechanism of the present invention, FIGS. 2 and 3 are a perspective view and a rear perspective view before assembly of the tensioning mechanism of FIG. 1, respectively, and FIGS. 1 is an AA cut end view, a BB cut end view, a CC cut end view, and a DD cut end view. FIG. 5 is a view of a window regulator using the tensioning mechanism of FIG. FIG. 6 is a front view showing a state during operation of the tension release mechanism of FIG. 1, FIG. 7 is an end view taken along the line EE of FIG. 6, and FIG. 8 is a view of the tension release mechanism of FIG. FIG. 9a and FIG. 9b are end views taken along the lines GG and FF of FIG. 8, respectively, and FIG. 10 is a perspective view showing the state of completion of the operation of the tensioning mechanism shown in FIG. Figures 11a and 11b are front views showing other embodiments of the guide member according to the present invention. It is.

  1 is used for a cable drive type window regulator (see FIG. 5), and is supported rotatably by a base 11, a shaft 12 fixed to the base, and the shaft. A guide member 13, an inner cable 14 engaged with the guide member, and a carrier plate (operating member) 15 with which one end of the inner cable is locked. The carrier plate 15 includes an engagement piece 16 that engages and rotates with the guide member 13. A center Q of the shaft 12 is a rotation center of the guide member 13.

  The base 11 is a substantially plate-like member, and as shown in FIG. 2, a through-hole 18 for fixing the base portion of the shaft 12 is formed at the center, and a pair of arc-shaped slits 19 are formed on the left and right sides thereof. Yes. The through hole 18 is hexagonal in this embodiment. Further, an annular seat surface 20 that receives the guide member 13 projects from the front surface of the base 11 (front side in FIG. 2) so as to surround the slit 19. Moreover, the cushion support part 21 for attaching a cushion member protrudes from the upper part of the front surface. The cushion support portion 21 is a columnar body having a substantially H-shaped or U-shaped cross section, and includes a pair of locking claws 22 for locking a rubber cushion (not shown) (see FIG. 1). The rubber cushion is a known one that relieves an impact when the lower end of the carrier plate 15 is received.

  Furthermore, in this embodiment, the outer latching | locking part 23 protrudes from diagonally upward (upper left of FIG. 2) of the front surface of the base 11. FIG. The outer locking portion 23 is a portion that supports an end portion of the outer casing 24 that slidably guides the inner cable 14, and has a stepped portion that locks a casing cap 25 that is fixed to the end portion of the outer casing 24. The groove 26 is formed. On the inner surfaces of the left and right walls 27 and 28 constituting the outer locking portion 23, a pair of locking pieces 23a that allow insertion from the front side of the casing cap 25 and prevent it from coming out protrudes. The inner cable 14 coming out of the outer casing 24 is engaged with the guide member 13 and turned upward, extends upward, and the tip is locked to the carrier plate 15. Thereby, the inner cable 14 is routed along a substantially U-shaped route.

  Of the left and right walls 27, 28, the right wall 28 is continuous via the cushion mounting portion 21 and the thick standing wall 29. A locking step 30 is recessed on the right side of the standing wall 29. As shown in FIG. 2, the left wall 27 constituting the outer locking portion 23 is continuous with the peripheral wall 31 protruding from the front surface along the peripheral edge of the base 11. The peripheral wall 31 is formed in an arc shape with the rotation center Q as the center.

  As shown in FIG. 3, a detent protrusion 32 protrudes on the back side of the base 11. The anti-rotation protrusion 32 stops rotation of the base 11 around the shaft when the base 11 is attached to the inner panel or module panel to which the window regulator is attached by the shaft 12. The anti-rotation protrusion 32 is provided with a retaining piece 33 that is elastically deformed. The base 11 is usually integrally formed of a synthetic resin such as polybutylene terephthalate (PBT). However, other materials such as metal can be used.

  As shown in FIG. 2, the guide member 13 includes a cylindrical base portion 34 that is rotatably fitted around the shaft 12, and a cam portion that is formed of a substantially semicircular thick plate extending around the base portion. 35 and a thin plate-like presser plate 36 extending from the periphery of the front surface side of the cam portion. A hole 34 a having a circular cross section through which the shaft 12 passes is formed at the center of the base portion 34. The guide member 13 is molded from a synthetic resin having high slidability, such as polyacetal (POM). An annular sliding contact surface 34 b that is shallowly recessed is formed on the front side of the base portion 34. Further, a pair of engaging tongue pieces 37 that are engaged with the head portion of the shaft 12 project forward from the vicinity of the outer periphery of the sliding contact surface 34b. The locking tongue piece 37 is for temporarily fixing the shaft 12 before fixing it to a panel (not shown). As shown in FIG. 3, an annular recess 34 c is formed on the back side of the base portion 34 so as to be able to rotate freely with the annular seating surface 20 of the base 11. An engagement tongue piece 38 for engaging with the slit 19 and temporarily fixing it protrudes. None of the engaging tongues 37, 38 has a substantial effect after the shaft 12 is secured to the panel.

  As shown in FIG. 1, the upper right end portion of the cam portion 35 is a first contact surface 40 that contacts the cushion support portion 21 of the base 11 and defines the first rotation end of the guide member 13. (See FIG. 2). On the other hand, the lower left end is a second abutting surface 41 that abuts the standing wall 29 of the base 11 and defines a second rotating end (see FIG. 2).

  A guide groove 42 is formed on the outer peripheral surface of the cam portion 35 to engage and slide the inner cable. The cross-sectional shape of the guide groove 42 is substantially U-shaped or substantially V-shaped (see FIG. 2). As shown in FIG. 3, the outer peripheral surface of the cam portion 35 has an arc shape centered on the rotation center, but the bottom of the guide groove 42 has a rotation center Q of the guide member 13 as shown by a broken line in FIG. The distance L is not an equal distance from the distance, but changes smoothly according to the angular position. That is, as shown in FIG. 1, the distance L is short in the vicinity of the first contact surface 40, gradually increases in the clockwise direction, and becomes maximum at the diagonally lower right in FIG. Then, it gradually becomes shorter again from the lower right to the lower end, and the guide groove 42 extends substantially linearly from the lower end to the lower left. The distance between the straight line and the rotation center Q is the minimum value of the distance between the guide groove 42 and the rotation center Q. The change in the distance L from the rotation center Q of the guide groove 42 constitutes a first return prevention means for preventing the rotation in the return direction when the guide member 13 reaches the second rotation end.

  The presser plate 36 provided on the front side of the cam portion 35 is in sliding contact with the upper end of the peripheral wall 31 of the base 11 and acts as a stopper to prevent the inner cable from coming out of the guide groove 42. On the front surface side of the presser plate 36, from the vicinity of the first contact surface 40, the engagement protrusion 44 that is pressed by the lower end of the engagement piece 16 of the carrier plate 15 protrudes outward in the radial direction and toward the front surface side. Yes. The end 44a on the first contact surface 40 side of the engagement protrusion 44 is formed in an arc shape so that the contact position with the contact piece 16 changes smoothly when the guide member 13 rotates.

  From the vicinity of the second contact surface 41 on the front surface of the presser plate 36, a thin plate-like lock tongue piece 45 projects in the circumferential direction. A locking projection 46 that engages with the locking step 30 of the standing wall 29 of the base 11 when the guide member 13 rotates to the second rotation end is formed on the back side of the tip of the locking tongue 45. Has been. The locking projection 46 is preferably provided with a taper on the distal end side so that it can easily ride on the standing wall 29, and on the proximal end side so as to be firmly engaged with the locking step portion 30 (see FIG. 9b). . When the guide member 13 reaches the second rotation end, the engagement step portion 30 and the lock tongue 45 act as second return prevention means for preventing rotation in the return direction.

  As shown in FIGS. 2 and 3, the shaft 12 includes a front end portion 12 a that is passed through and fixed to a panel (not shown), and a hexagon that is thicker than the front end portion and is inserted through the through hole 18 of the base 11. A columnar fitting portion 12b, a columnar support portion 12c that is thicker than the fitting portion 12b and rotatably supports the guide member 13, and a sliding contact surface 34a on the front surface of the guide member 13 are slidably engaged. And a flange 12d for preventing the guide member 13 from coming off. The distal end portion 12a forms a male screw and is fastened with a nut. The shaft 12 is usually made of a metal such as steel. However, a synthetic resin may be used.

  The base 11, the shaft 12, and the guide member 13 configured as described above are temporarily coupled in a state where the inner cable 14 is engaged with the guide groove 42 of the guide member 13, as shown in FIGS. 1, 4c, and 9a. The That is, the inner cable 14 is engaged with the guide member 13, and in this state, the front end of the engagement tongue piece 38 on the back side is inserted into the slit 19 of the base 11 and temporarily coupled. At this time, centering can be performed by fitting the annular seat surface 20 and the annular recess 34c. Next, the shaft 12 is inserted into the hole 34a of the guide member 13 and the through hole 18 of the base 11, and the flange 12d is engaged with the engaging tongue 37 on the front surface of the guide member. Thereby, the cable guide device 50 in a temporarily coupled state is obtained. In this temporarily coupled state, as shown in FIGS. 4 b and 4 c, the guide groove 42 is blocked by the base 11, so that the inner cable 14 does not fall off the cable guide device 50. Alternatively, the cable guide device 50 does not fall off from the inner cable 14. The obtained cable guide device 50 is fixed by inserting the tip end of the shaft 12 into an opening formed in the inner panel or the module panel and fastening with a nut. At this time, the anti-rotation protrusion on the back side of the base 11 is inserted into the hole formed in the panel, and the anti-rotation effect is exhibited.

  The cable guide device 50 fixed in this way constitutes the aforementioned tension release mechanism 10 together with the carrier plate 15 of FIG. The carrier plate 15 is shown with a glass holder 53 attached by bolts 52 (see FIG. 4a). The glass holder 53 includes a glass fixing portion 54 having a substantially U-shaped cross section that is fixed to the lower end of the window glass with an adhesive or the like, and a connecting portion 55 that extends downward from the lower end of the glass holder 53 (FIG. 2). reference). As shown in FIG. 1, the lateral width of the glass fixing portion 54 is substantially the same as the width of the carrier plate 15, and the lateral width of the connecting portion 55 is narrower.

  As shown in FIG. 4a, an engagement step portion 56 that engages with the upper surface of the carrier plate 15 is formed on the back side of the glass fixing portion 54 (see FIG. 3). The glass holder 53 is entirely made of synthetic resin, and a metal nut 57 screwed into the bolt 52 is embedded in the connecting portion 55 by insert molding or the like. The bolt hole through which the bolt 52 of the carrier plate 15 is passed is reinforced with a metal ring. In this embodiment, a bolt with a hook is used as the bolt 52.

  As shown in FIG. 2, the carrier plate 15 is provided with a receiving portion 58 that receives the connecting portion 55 of the glass holder 53 while guiding it. At the right end of the carrier plate 15, a cable locking portion 59 for locking the end portion of the downward driving inner cable 14 extending downward is provided so as to protrude obliquely upward. As shown in FIG. 3, the cable locking portion 59 has a U-shaped cross section, and the cable end 14 a of the inner cable 14 is locked via the compression coil spring 60 therein. The cable locking portion 59, the compression coil spring 60, and the cable end 14a constitute an elongation absorbing mechanism (tension maintaining mechanism). The cable locking portion 59 is covered with a cover (reference numeral 61 in FIG. 1), and the front side and upper end openings are closed. Reference numeral 59a in FIG. 1 is an introduction groove for changing the direction of the inner cable 14. Below the cable locking portion 59, the aforementioned engagement piece 16 projects downward. By bringing the cable locking portion 59 and the engagement piece 16 closer, the torque based on the reaction force when the engagement piece 16 pushes down the guide member 13 can be reduced.

  As shown in FIG. 3, a cable locking portion 63 for locking the cable end 62 a of the upward driving inner cable 62 extending upward is provided on the back side of the carrier plate 15. The cable locking part 63 includes a cylindrical hole for inserting the cable end 62a and an introduction groove 63a communicating with the hole. The cylindrical hole opens on the right side of FIG. The introduction groove 63a has an L shape when viewed from the back side. As a result, the inner cable 62 for driving up is inserted into the cylindrical hole with the cable end 62a extending in the back side (front side in FIG. 3), and then the cable end so as to extend the inner cable 62 upward. 62a is rotated in the hole.

  The inner cable tensioning mechanism 10 configured as described above is used, for example, in a window regulator 65 that drives the window glass W of the front door 64 of the automobile shown in FIG. 5 up and down. The window regulator 65 includes an inner panel 66, the above-described cable guide device 50 attached to the lower left of the inner panel 66 (below the front side of the automobile), and cable guide devices 67a attached to the upper left, upper right, and lower right. 67b, 67c, and an inner cable loop 68 connected between the cable guide devices in an approximately eight-letter shape, and a portion extending in the vertical direction of the inner cable loop. Left and right carrier plates 15 and 69 and a cable driving device 70 for reciprocatingly driving the loop 68 of the inner cable.

  The upper left, upper right, and lower right cable guide devices 67a to 67c each include a base, a shaft for attaching the base to the inner panel 66, and a pulley that is rotatably supported by the shaft and engages with the inner cable. Consists of. The base is provided with a cover for closing the guide groove around the pulley. Thereby, the inner cable is prevented from falling off from the cable guide devices 67a to 67c. However, a cable guide device including only a pulley and a shaft may be used. As the cable driving device 70, a known device including a drum that winds one end of the loop 68 of the inner cable and feeds the other, a motor M that drives the drum to reciprocate, and a speed reducer is used.

  One end of the loop 68 of the inner cable is locked to the drum of the cable driving device 70 and the vicinity thereof is wound, extends to the lower left and is turned upward by the lower left cable guide device 50, and the other end is turned to the left. The above-described lower drive inner cable 14 that is locked to the carrier plate 15, and extends upward from the left carrier plate 15, is redirected by the upper left cable guide device 67 a, extends in the lower right direction, and extends in the lower right cable. The above-mentioned inner cable 62 for upward driving that is turned upward by the guide device 67c and the other end is locked to the right carrier plate 69, and one end is locked to the right carrier plate 69 and extends upward, The cable guide device 67b on the upper right turns the direction diagonally downward, and the other end is the driver of the cable drive device 70. Locked to, constituted by three of the inner cable of the inner cable 72 near its wound. However, the carrier plate 15 can also be locked in the middle of the inner cable. The inner cable 62 for driving up for the left carrier plate 15 is for driving down for the right carrier plate 69.

  In the window regulator 65, the right carrier plate 69 also employs an extension absorbing mechanism using a compression coil spring similar to the left carrier plate 15. These elongation absorbing mechanisms are for preventing the inner cables 14 and 62 sent out from the cable driving device 70 from being loosened, and the compression coil spring is in a compressed state at the initial stage of use. There is a need. Further, when permanent elongation occurs in the inner cable after long-term use, it is also useful to absorb the permanent elongation.

  In order to assemble the window regulator 65 described above, the entire cable guide device 50, 67a, first, with the guide member 13 of the lower left cable guide device 50 rotated to the first rotation end as shown in FIG. 67b, 67c and the cable driving device 70 are attached to the inner panel. In the state of FIG. 1, the position P having the maximum distance L from the rotation center Q of the guide groove 42 (hereinafter referred to as “maximum radius position”) P is closer to the right end, and therefore the inner cable routing route is short. . Therefore, there is a margin in this portion of the inner cable, the compression coil spring of the elongation absorbing mechanism is somewhat extended, and the tension of the inner cable is weakened. Therefore, assembly work is easy.

  After the cable guide devices 50, 67a, 67b, 67c and the cable driving device 70 are attached to the inner panel, the motor M of the cable driving device 70 is operated so that the drum rotates counterclockwise. As a result, the loop 68 of the inner cable circulates in the direction of lowering the window glass, the left and right carrier plates 15 and 69 are lowered synchronously, and the window glass W is lowered. Then, the lower end of the engagement piece 16 of the left carrier plate 15 is engaged with the engagement protrusion 44 of the guide member 13 (see FIG. 1), and when the motor M is further rotated, the guide member 13 is rotated clockwise (FIG. 1, FIG. 1). In the case of 2, it rotates in the counterclockwise direction in FIG. As a result, the routing route becomes gradually longer, and when the position P of the maximum radius reaches a position that divides the angle formed by the left and right inner cables into two, the routing route becomes the longest (top dead center). When the wiring path becomes long in this way, tension is generated in the inner cable 14 accordingly, and tension is applied to the entire loop 68 of the inner cable.

  When the motor M is further rotated in the same direction and the top dead center is exceeded, the routing path gradually becomes shorter. Therefore, even if the engagement piece 16 does not push down the engagement protrusion 44, the guide is caused by the tension of the inner cable 14. The member 13 is urged clockwise (in FIG. 5, counterclockwise). Therefore, the guide member 13 is rotated clockwise as it is (counterclockwise in FIG. 5), and the second abutting surface 41 abuts against the standing wall 29 of the base 11 as shown in FIGS. The movement stops. At that time, as shown in FIG. 9b, the lock tongue 45 is engaged with the locking step portion 30, and the rotation is locked. The carrier plate 15 descends as it is and comes into contact with the cushion of the base 11 and stops.

  In the state of FIG. 8 where the guide member 13 has reached the second rotation end, the length of the routing path is shorter than the top dead center, but is sufficiently longer than the first rotation end, so that the inner cable Appropriate initial tension is applied to 14, and that tension extends to the entire inner cable loop 68. Thereafter, the window glass W can be moved up and down through the loop 68 of the inner cable to which an appropriate tension is applied by reciprocatingly rotating the motor of the cable driving device.

  When assembling as described above, if the length of the routing path of the inner cable loop 68 is shortened to loosen the inner cables 14, 62, 72, the compression coil spring 60 in the carrier plate 15 will interfere with the assembly. Return to no length. Therefore, it is not necessary to attach the cable guide devices 50, 67 a, 67 b, 67 c to the inner panel 66 against the strong biasing force of the compression coil spring 60. Therefore, the assembly work is facilitated. When the wiring path is lengthened and tension is applied to the inner cables 14, 62, 72 at the final stage of the assembling work, the compression coil spring 60 is compressed. Therefore, when the cable driving device 70 winds up one end of the loop 68 of the inner cable and feeds out the other end for raising and lowering the window glass W, the compression coil is likely to loosen on the fed-out side. The spring 60 extends to remove slack (elongation absorption). Moreover, even if it uses for a long period of time and permanent elongation arises in an inner cable, the elongation can be absorbed.

  In the embodiment, the first return preventing means is configured by the guide member 13 reaching the second rotation end in a state where the top dead center is exceeded, and the second locking means having the lock tongue 45 is used for the second return. Although the return preventing means is used, the second return preventing means may be omitted. In addition, by setting the top dead center as the second rotation end, the first return prevention means can be omitted, and the return prevention means can be configured only by the lock means. Further, the guide member 13 can be elastically biased in the return direction until it reaches a predetermined angle, and if it exceeds that angle, it can be used as a return preventing means by a center over spring that elastically biases in the forward direction. Further, the ratchet mechanism may be used as a guide member return prevention means.

  In the window regulator 65 of FIG. 5, the tension releasing mechanism 10 is adopted for the lower left cable guide device 50 and the left carrier plate 15 among the four cable guide devices 50, 67 a, 67 b, 67 c on the upper, lower, left and right sides. It is also possible to employ a tensioning mechanism for the other cable guide devices 67a, 67b, 67c and the carrier plates 15, 69 corresponding thereto. Furthermore, a tensioning mechanism can be employed for two or more cable guide devices and the carrier plate.

  The window regulator 65 in FIG. 5 is a window regulator for a front door in which an inner cable loop 68 is routed in an 8-shape with respect to four cable guide devices. The tension release mechanism of FIG. 1 can also be employed in a window regulator for a rear door in which the inner cable is arranged in a triangular shape using the device. In this case as well, the tensioning mechanism can be used for either the upper or lower cable guide device and the corresponding carrier plate, and it can also be used for both.

  The window regulator 65 of FIG. 5 does not use an outer casing that guides the loop 68 of the inner cable, but an obliquely extending portion may be guided by the outer casing. The same applies to the window regulator for the rear window. Further, in the window regulator 65 of FIG. 5, guide rails for guiding the raising and lowering of the carrier plates 15 and 69 are not employed, but they may be employed. However, the inner cable tensioning mechanism is more effective when used in a so-called railless type window regulator that does not include a guide rail.

  In the embodiment of FIG. 5, the case where the base of the cable guide device is attached to the inner panel has been described. However, the cable guide device may be attached to a flexible module panel made of synthetic resin or the like. The flexible module panel is bent due to the tension of the inner cable, and the mounting pitch to the door panel changes, so it is difficult to accurately mount the door panel, but after mounting the module panel to the inner panel, By performing tensioning with the above-described tensioning mechanism, attachment to the door panel can be performed accurately. Furthermore, in the case of a module panel made of synthetic resin, the base of the cable guide device can be integrally formed with the module panel, thereby reducing the number of parts. In the above-described embodiment, a motor-driven cable drive device is employed, but a cable drive device that rotates a drum with a manually operated crank handle may be employed.

  In the above-described embodiment, the distance from the rotation center Q of the guide member 13 to the bottom of the guide groove 42 is smoothly changed according to the angle. It is a major factor in changing length. However, for example, like the guide members 74 and 75 shown in FIGS. 11a and 11b, the shape of the cam portion 35 is substantially semicircular or fan-shaped, and the distance L from the rotation center Q of the guide groove 42 is a substantially constant circular arc shape. Even so, the length of the routing route can be changed. In the case of the guide member 74 of FIG. 11a, when the guide member 74 is inverted by about 180 degrees, the cabling length when the arc-shaped portion of the cam portion 35 is directed downward (solid line state) is upward ( It can be longer than the length of the imaginary line.

  Further, as shown in FIG. 11 b, the length of the routing path also changes depending on the positional relationship between the support positions 75 and 76 of the inner cable 14 and the guide groove 42. That is, when the guide member 75 is at the first rotation end (solid line state), the left side of the inner cable 14 protrudes inward from the tangential direction of the arc of the guide groove 42. That is, it passes through a circle whose center is the rotation center Q and whose radius is the distance from the rotation center Q to the guide groove 42. On the other hand, when it comes to the second rotation end (in the imaginary line state), it protrudes in the substantially tangential direction of the guide groove 42. Thereby, the length of the wiring path in the 2nd rotation end becomes longer than the length of the wiring path in the 1st rotation end. In the embodiment of FIG. 1 as well, the routing route is changed not only by the change of the routing route depending on the shape of the guide groove 42 but also by the way the inner cable is separated from the guide groove.

  11a and 11b, in the vicinity of the end portion of the guide groove 42, the inner cable 14 is formed in a round shape having a radius equal to or larger than the minimum bending radius in order to prevent the inner cable 14 from being bent sharply.

  The tension raising mechanism of the present invention can be employed not only in a window regulator in which a window glass moves up and down, but also in one that slides left and right and opens and closes and opens and closes on a horizontal plane. In addition to the window regulator, the tension output mechanism of the present invention can be employed in a cable guide device in a device that reciprocally operates an operation member with an inner cable arranged in an 8-letter or triangular shape. In an apparatus that does not use a carrier plate, the engaging piece is fixed directly to the inner cable.

It is a front view which shows one Embodiment of the tension taking-out mechanism of this invention. It is a perspective view before the assembly of the tension taking mechanism of FIG. FIG. 2 is a rear perspective view of the tension release mechanism of FIG. 1 before assembly. 4a to 4d are an AA line cut end view, a BB line cut end view, a CC line cut end view, and a DD line cut end view of FIG. 1, respectively. It is a front view which shows one Embodiment of the window regulator using the tension taking-out mechanism of FIG. It is a front view which shows the state in the middle of the action | operation of the tension | tensile_strength mechanism of FIG. FIG. 7 is an end view taken along line E-E in FIG. 6. It is a front view which shows the operation completion state of the tension taking mechanism of FIG. 9a and 9b are a sectional view taken along line GG and a sectional view taken along line FF in FIG. 8, respectively. It is a perspective view which shows the operation completion state of the tension taking mechanism of FIG. 11a and 11b are front views showing other embodiments of the guide member according to the present invention. It is a front view which shows an example of the window regulator provided with the conventional tension | tensile_strength mechanism.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Tensioning mechanism 11 Base 12 Shaft 13 Guide member 14 Inner cable 15 Carrier plate 16 Engagement piece Q Rotation center 18 Through-hole 19 Slit 20 Seat surface 21 Cushion support part 22 Locking claw 23 Outer lock part 24 Outer casing 25 Casing cap 26 Stepped groove 27, 28 Wall 23a Locking piece 29 Standing wall 30 Locking step 31 Peripheral wall 32 Anti-rotation protrusion 33 Lock-off piece 34 Base 34a Hole 34a Sliding surface 34b Recess 35 Cam part 36 Press plate 37 Engaging tongue (front)
38 Engaging tongue (back)
40 First contact surface 41 Second contact surface 42 Guide groove L Distance 44 from the center of rotation to the bottom of the guide groove 44 Engagement protrusion 45 Lock tongue piece 46 Engagement protrusion 12a Tip part 12b Fitting part 12c Support part 12d Flange 50 Cable guide device 52 Bolt 53 Glass holder 54 Glass fixing part 55 Connection part 56 Engagement step part 57 Nut 58 Receiving part 59 Cable locking part 60 Compression coil spring 14a Cable end 61 Cover 62 Inner cable 62a for driving up the cable End 63 Cable locking part 63a Introduction groove 64 Front door 65 Window regulator 66 Inner panel 67a, 67b, 67c Cable guide device 68 Inner cable loop 69 (on the right) Carrier plate 70 Cable drive device 72 Inner cables 74, 75 Guide member 6,77 support position

Claims (5)

A support member, a guide member having a substantially arc-shaped guide groove attached to the support member, an inner cable slidably engaged with the guide groove of the guide member, and a direction change; and the inner cable An operating member that is locked and driven to reciprocate in the tension direction of the inner cable as the inner cable reciprocates,
The guide member is attached to the support member so as to be rotatable between a first rotation end and a second rotation end,
The routing path passing through the guide groove at the second rotation end is configured to be longer than the routing path passing through the guide groove at the first rotation end,
An engaging piece that engages with the guide member to rotate the guide member from the first rotation end to the second rotation end when the actuating member moves in a direction approaching the guide member;
After the guide member reaches the second rotation end, the guide member includes return preventing means that does not return to the first rotation end side.
Inner cable tensioning mechanism.   The guide member is configured such that a routing path in the middle of the first rotating end and the second rotating end is longer than a routing path at the second rotating end, thereby serving as the return preventing means. The inner cable tensioning mechanism according to claim 1.   Between the guide member and the support member, there is provided locking means that engages with each other and prevents the guide member from returning when the guide member reaches the second rotation end, and the locking means is 2. A tensioning mechanism for an inner cable according to claim 1, which is a return preventing means.   4. The inner cable according to claim 1, 2, or 3, wherein the change in the length of the routing path is caused by a smooth change in the distance from the rotation center of the guide member to the bottom of the guide groove. Tensioning mechanism. An upper guide member and a lower guide member respectively attached to the upper part and the lower part;
An inner cable that is stretched between the upper and lower guide members, is changed in direction by those guide members, and the direction-changed portions are alternately pulled and operated,
A carrier plate locked to a region stretched between upper and lower guide members in the inner cable;
A window regulator comprising a cable driving device that alternately reciprocates the inner cable,
A window regulator in which the tension releasing mechanism according to any one of claims 1 to 4 is used for at least one of the upper guide member and the lower guide member.

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