WO2005013748A1

WO2005013748A1 - Clamping device for traction cables, especially traction cable tie-ups in shoes

Info

Publication number: WO2005013748A1
Application number: PCT/EP2004/051691
Authority: WO
Inventors: Shoichi Murabe
Original assignee: Japana Co., Ltd.
Priority date: 2003-08-04
Filing date: 2004-08-02
Publication date: 2005-02-17
Also published as: CN1826065A; DE10335940A1; JP2007501038A; CN100409785C; EP1651073B1; KR20060024377A; JP4538836B2; KR100804588B1; EP1651073A1; ATE414437T1; DE502004008495D1

Abstract

The invention relates to a traction device which produces large transmission when the tension of the traction cable is reduced and/or is zero, such that during rotation of a handwheel, lengths of the traction cable can vary significantly. As soon as the tension of the traction cable exceeds a threshold value, the clamping device produces transmission in a slow manner such that rotation of the handwheel produces comparatively small variations of the length of the traction cable and enables the clamping force to be adjusted in a delicate manner.

Description

Description TENSIONING DEVICE FOR TOWING CABLES, ESPECIALLY TOWING CABLE LACING ON SHOES

The invention relates to a tensioning device for pull cables, in particular pull cord laces on shoes, with at least one cable drum connected or connectable to the pull cable or pull cables, a handwheel for rotating the cable drum or cable drums, one between the handwheel and Cable drum or cable drums arranged gear with slow translated through drive from the handwheel to the cable drum or the cable drums and a switch-off backstop, which only allows rotation of the cable drum or cable drums in the tensioning direction of the pull cable or the pull cable in the effective state. Shoes with pull cord lacing and associated tensioning devices which are operated by means of a handwheel are available on the market. In these clamping devices on the one hand constructions are known in which the handwheel is forcibly coupled directly to the cable drum at least when rotating in the direction of rotation provided to increase the tension of the pull cable and the cable drum accordingly executes the same angle of rotation as the handwheel. In this context, reference can be made, for example, to EP 0 651 954 B1, EP 0 540251 AI and AT-PS 195751. With such constructions it is advantageous that a greater change in the length of the pull cable can be achieved with a comparatively small rotation adjustment of the handwheel. On the other hand, clamping devices are also known in which a gear is arranged between the handwheel and cable drum, which translates the rotary movements of the handwheel into slow motion. When the pull cable is shortened, the cable drum performs a significantly reduced turning stroke relative to the handwheel. With regard to such constructions, reference can be made, for example, to US 4,961,544, US 6,202,953 B1 and US 6,289,558 B1. An advantage of such tensioning devices provided with gears is that even very small changes in the length of the pull cable and correspondingly minor changes in the tension can be easily adjusted. [005] The company BOA Technology, Inc. also offers spa devices provided with planetary gears, so that, despite the gearing, only a small construction volume is required. The object of the invention is now to enable a particularly convenient and fast operation in a tensioning device of the type specified.

This object is achieved in that a direct frictional connection is provided between the handwheel and cable drum or cable drums and the transmission is free of forced coupling when the cable drum or cable drums rotate in the tensioning direction in the direction of the handwheel.

The invention is based on the general idea of providing two drive connections between the handwheel and the cable drum or cable drums for their movement in the tensioning direction, namely a frictional connection that is only suitable for achieving low savings forces and a positive connection that is suitable in principle for any high tensioning forces. The positive-locking connection has a translation into slow motion relative to the non-positive connection, so that when the tensioning cable is loose, the positive-locking connection first becomes effective and enables the loosening of the tensioning cable to be eliminated quickly, while the positive-locking connection then automatically takes effect when a threshold value of the clamping force specified by the non-positive connection is exceeded and enables a very sensitive adjustment of the desired clamping force. To implement this concept, the gear mechanism that realizes the positive-locking connection can be designed in such a way that the cable drum or the cable drums is associated with a freewheel that is effective in the tensioning direction and is inhibited by limited forces.

According to a particularly preferred embodiment of the invention, a non-positive locking mechanism can be arranged between the handwheel and cable drum or cable drums. The latching force thus specifies the maximum torque that can be transmitted by frictional connection. Furthermore, it is advantageous that an exceeding of the latching force is clearly perceptible and haptic control is therefore provided for whether the cable drum or cable drum is adjusted in the tensioning direction by the handwheel solely by frictional engagement or via the form-fitting gear mechanism.

According to a particularly expedient and compact embodiment of the invention, a planetary gear is arranged between the handwheel and cable drum or cable drums, the sun wheel of which is positively coupled to the handwheel and the planet carrier of which is connected to the cable drum or cable drums and the ring gear of which is in the same direction of rotation as the clamping direction of the planet carrier is rotatable, so that the necessary freewheel is given in order to be able to adjust the cable drum or the cable drums with the handwheel solely via the frictional connection in the tensioning direction.

In this embodiment, the planet carrier can in a particularly advantageous manner relative to the ring gear against rotation against the clamping direction by a the first lock is locked and the ring gear is assigned a releasable second lock which, in the active state, only permits movement of the ring gear which is in the same direction as the tensioning direction of the planet carrier.

In particular, it can be provided that the planet carrier and ring gear are coupled via the first lock in the opening direction thereof with a force fit which is greater than the inhibitory forces exerted by the second lock on the ring gear when it rotates in the freewheeling direction of the second lock.

In this embodiment, the first lock has a double function:

On the one hand, when the second lock is effective, it prevents the cable drum or cable drums from rotating in the direction of relief of the pull cable or the pull cables. On the other hand, the first lock causes a frictional connection between the planet carrier and the ring gear, so that with low tension of the pull cable or the pull cable sun gear planet carrier and ring gear can carry out the same and the same directional rotations in the tensioning direction and accordingly a quick adjustment of the pull cable or the pull cable can take place.

For the rest, with regard to preferred features of the invention, reference is made to the claims and the following explanation of the drawing, on the basis of which particularly preferred embodiments of the invention are described in more detail. The scope of protection is of course not limited to the expressly claimed or shown combinations of features, rather protection is also claimed for basically any sub-combinations of the features.

[016] In the drawing:

1 shows a schematic axial section of a tensioning device according to the invention with a planetary gear,

[018] FIG. 2 shows a schematic cross section corresponding to the sectional plane II-1T in FIGS. 1 and

3 shows a schematic cross section corresponding to the cutting plane HI-HI in FIG. 1.

Within a housing 1, a shaft 2 is rotatably mounted, on the outside of the housing 1, a handwheel 3 and within the housing 1, a sun gear 4 of a planetary gear 5 accommodated in the housing 1 is arranged in a rotationally fixed manner. The planetary gear 5 has a ring gear 6 which is rotatably mounted on the shaft 2 and a planet carrier 7 which is also rotatably mounted on the shaft 2. This is rotatably connected via the axes of its planet gears 8 to a cable drum 9 which is rotatably mounted on the shaft 2 and which in turn is connected to pull cables 10 is.

The planet gears 8 have a conventional toothing which meshes with corresponding toothing on the outer circumference of the sun gear and on the inner circumferential region of the ring gear 6 assigned to the planet gears 8. In the axial region of the planet carrier 7, a sawtooth-like toothing is arranged on the inner circumference of the ring gear 6 according to FIG. 3, into which spear pawls 11 arranged or molded on the planet carrier 7 engage in one circumferential direction and engage in the other circumferential direction. Accordingly, the planet carrier 7 in the example of FIG. 3 can be rotated clockwise relative to the ring gear 6. Counter-clockwise, the planet carrier 7 can be rotated relative to the ring gear 6 against the latching resistance which the pawls 11 bring about in the aforementioned inner peripheral toothing of the ring gear.

On the outer circumference of the ring gear 6 is a further sawtooth-like toothing, which interacts with a manually triggered pawl 12 arranged on the housing 1. In the effective state of the pawl 12, the ring gear 6 can be rotated relative to the housing 1 in the example of FIG. 3 only counterclockwise, i. H. the possible direction of rotation of the ring gear 6 relative to the housing 1 is directed in the same direction as the possible rotation of the planet carrier 7 relative to the ring gear 6. The locking force which counteracts a rotation of the ring gear 6 counterclockwise by the pawl 12 is less than the master force, which of the pawls 11 of a rotation of the planet carrier relative to the ring gear 6 is opposed.

The arrangement illustrated works as follows:

When looking in the direction of arrow P in Fig. 1, the handwheel 3 is rotated counterclockwise to tension the cable 10 when the sawtooth-like teeth on the outer and inner circumference of the ring gear are aligned according to FIG. 3.

[026] First, the cables 10 may have a loose, i.e. H. the tensile stress of the cables 10 is initially negligible. If the handwheel 3 is now turned counterclockwise, the locking force caused by the pawls 11 between the planet carrier 7 and the ring gear 6 cannot yet be overcome. Accordingly, the handwheel 3, the sun gear 4, the planet carrier 7 and the ring gear 6 have the same direction of rotation and the same size. This is equivalent to the fact that the cable drum 9, which is connected to the planet carrier 7 in a rotationally fixed manner, executes the same rotational movement as the handwheel 3 in the tensioning direction of the cables 10. As a result, the slack in the cables 10 can be quickly eliminated.

Now the tensile stress of the cables 10 may exceed a threshold value determined by the inhibiting force present between the ring gear 6 and the planet carrier 7. If the handwheel 3 is now rotated further counterclockwise, a sufficiently large torque is transmitted clockwise from the sun gear 4 via the planetary gears 8 to the ring gear 6, such that the ring gear 6 attempts to rotate clockwise; however, such a rotational movement is effective Pawl 12 prevents, ie the ring gear 6 remains stationary relative to the housing 1. Corresponding to the transmission ratio of the planetary gear 5, the planet carrier is now moved further with a slower rotation than the rotation of the handwheel 3, so that the cable drum 9 is also rotated correspondingly slowly in the tensioning direction of the cables 10. As a result, the lengths and tension forces of the pull cable 10 can be set very sensitively.

If the pull cable 10 is to be loosened or released, the pawl 12 is pivoted manually in accordance with the arrow Q in FIG. 3, so that the ring gear 6 and thus also the cable drum 9 rotate clockwise and accordingly in the relaxation direction of the cable 10 can turn. This rotation can be supported by a corresponding manual rotation adjustment of the handwheel 3 in the clockwise direction.

[029]

Claims

Expectations

Tensioning device for pull cable (10), in particular of pull cable lacing on shoes, with - at least one cable drum (9) connected or connectable to the pull cable or the pull cables - a handwheel (3) for rotating the cable drum or cable drums , - a gearbox (5) arranged between the handwheel and cable drum or cable drums with slow through-drive from the handwheel to the cable drum or cable drums and - a reversible backstop (11, 12), which in the effective state only rotates the cable drum or Allows cable drums in the tensioning direction of the pull cable or pull cables, characterized in that a direct frictional connection (6, 11) is provided between the handwheel and the cable drum or cable drums and the gearbox is force-coupled when the cable drum or cable drums rotate in the tensioning direction in the direction of the handwheel. is lung-free.

Clamping device according to claim 1, characterized in that a non-positive locking mechanism (6, 11) is arranged between the handwheel (3) and cable drum (9) or cable drums.

Clamping device according to claim 1 or 2, characterized in that between the handwheel (3) and cable drum (9) or cable drums a planetary gear (5) is arranged, the sun gear (4) with the handwheel and the planet carrier (7) with the cable drum or the cable drums are forcibly coupled and the ring gear (6) thereof can be rotated in the same direction of rotation as the clamping direction of the planet carrier.

Clamping device according to claim 3, characterized in that the planet carrier (7) relative to the ring gear (6) locked against rotation against the clamping direction by a first lock (11) and the ring gear is assigned a releasable second lock (12) in the active state only allows the ring gear to rotate in the same direction as the clamping direction of the planet carrier.

[005] Clamping device according to claim 4, characterized in that that planet carrier (7) and ring gear (6) in the opening direction of the first lock (11) are coupled with a force fit which is greater than the inhibiting forces exerted by the second lock (12) on the ring gear when it rotates in the freewheeling direction of the second lock become.

Clamping device according to claim 4 or 5, characterized in that resilient pawls (11) are arranged or formed on the planet carrier (7), which cooperate with an associated, asymmetrical tooth shape having inner peripheral teeth on the ring gear (6) and relative rotations of the planet carrier and ring gear Lock in one direction by positive locking and allow in the other direction against frictional engagement generated by locking resistance.

Clamping device according to claim 5 or 6, characterized in that a manually releasable pawl arrangement (12) with an asymmetrical tooth shape having external peripheral teeth on the ring gear (6) cooperates and rotations of the ring gear in one direction by positive locking and rotations in the other direction only inhibits with a small frictional connection generated by latching resistance, which is less than the frictional connection between handwheel (3) and cable drum (9) or cable drums and / or between planet carrier (7) and ring gear (6).