The present application claims priority under 35 U.S.C. § 119 to European Patent Publication No. EP 18163298.5 (filed on Mar. 22, 2018), which is hereby incorporated by reference in its complete entirety.
Embodiments relate to a hook clamp comprising a clamping hook with a hook element, the clamping hook being configured to be received in an opening of a component which is to be clamped.
Hook clamps are already known per se, and are used particularly in the automobile industry. Hook clamps may be used, for example, to clamp a vehicle body component against another vehicle component in the course of vehicle production. The component which is to be clamped must have an opening in this case, through which a clamping hook, provided with a hook, of the hook clamp is guided so that via the hook the component may then be pulled in the direction towards the hook clamp (“rearwards”) and in particular in the direction towards another component which is arranged between the component and a housing of the hook clamp.
The hook clamp may also be designed such that, during the pulling of the component which is to be clamped, the hook element is moved at the same time in a direction towards the hook (“downwards”). In that way, during the pulling movement the hook, the hook clamp may engage better in the component to be clamped and carry this along.
European Patent Publication EP 1 391 266 A2 discloses a centring clamp for the centred fixing of a component to be machined, comprising a centring pin which fits on an adapter plate and is arranged above a clamping hook, formed from a hook and hook arm, of the clamp drive, the centring pin having a through-slot for the clamping hook, wherein provision is made for protective elements, butting against the flanks of the clamping hook, for preventing entry of foreign objects into the tensioning-hook through-opening of the adapter plate. This known centring clamp has a centring pin which has to be guided through the component which is to be clamped, so the component requires a correspondingly large opening. Furthermore, the hook of the clamping hook in this embodiment is capable of relatively little movement in the transverse direction since its travel is limited by the centring pin. Therefore, the tool is less suited to larger component tolerances.
Embodiments relate to an enhanced design for a hook clamp which is useable, for example, in instances of larger component tolerances, and which facilitates a greater pulling force. Such a hook clamp requires only a small through-opening on the component which is to be clamped.
In accordance with embodiments, a hook clamp may comprise: a clamping hook configured to be received in an opening of a component which is to be clamped, the clamping hook having a first clamping hook arm with a hook element formed on a free end thereof, and a second clamping hook arm arranged at an angle relative to the first clamping hook arm; an actuator pivotably on the second clamping hook arm at a pivot point to displace or otherwise move the clamping hook from an open position in a pulling direction into a closed position in which the hook element is displaced (in addition to the pulling direction) in a direction towards the hooking end of the hook element, i.e. in a hooking direction; and a spring element configured to pre-tension the clamping hook against the pulling direction at a pre-tensioning position between the pivot point and the hook element, wherein the clamping hook, at a guiding position between the pivot point and the hook element, is displaceably mounted in an elongated hole in a direction parallel to the pulling direction.
In accordance with embodiments, the hook clamp comprises a clamping hook having two clamping hook arms which are arranged at an angle relative to each other. For example, the two clamping hook arms may be arranged approximately at a right angle relative to each other.
In accordance with embodiments, the first clamping hook arm includes the hook element which is configured to perform the pulling.
In accordance with embodiments, the second clamping hook arm, especially, for example, at its free end, is configured to be pulled at a pivot point with via the actuator. The pulling at the pivot point, i.e., a movement in a rearward direction, is to bring about a pulling of the hook element, and thus, clamping of a component which is to be clamped. The second clamping hook arm may be arranged approximately at a right angle to the first clamping hook arm.
In accordance with embodiments, the clamping hook is additionally mounted between two ends thereof in an elongated hole so as to be moveable, which is limited by the elongated hole, in a longitudinal direction (i.e., in the pulling direction). This longitudinal direction, i.e., the direction of the elongated hole, may approximately correspond to a direction of the first clamping hook arm.
In accordance with embodiments, the spring element is configured to act on the clamping hook. The spring element may be arranged between the pivot point and the hook. The spring element may be arranged on the first clamping hook arm, especially at the end of the first clamping hook arm of the clamping hook, in order to push this against the pulling direction, i.e., in a forward direction. The spring element may especially be a compression spring. The spring element may comprise a simple compression spring which in the main is orientated parallel to the first clamping hook arm.
In accordance with embodiments, as a result of the design of the hook clamp, it achieves the effect that during a pulling on the pivot point via the actuator in an open position of the hook clamp, the clamping hook is pulled in a rearward direction. But in the process of movement, the hook clamp is initially pushed in a forward direction at the pre-tensioning position via the force of the spring element. In that way, the guiding position initially remains at a forward end of the elongated hole and the hook element initially executes a movement in a downward direction, i.e., in the hooking direction, and only with further pulling via force of the actuator in the pulling direction is the guiding position shifted rearwards inside the elongated hole and the hook element is therefore pulled rearwards in order to clamp (if necessary) a component which is grabbed by the hook.
In accordance with embodiments, the direction towards the hook clamp, i.e., the pulling direction, is referred to herein as the rearward direction. The direction in which the hook is moved towards its front end for engaging in a component, i.e., the hooking direction, is referred to herein as the downward direction, and is approximately normal/perpendicular to the pulling direction.
In accordance with embodiments, for unclamping, i.e., for opening the hook clamp via the actuator, a force may be applied in opposition to the pulling direction so that both the actuator force and the force of the spring element collectively push the clamping hook in the forward direction. If the guiding position of the hook element reaches the front end of the elongated hole in the process, and therefore, movement of the hook element is limited or terminated, the hook element, with further force application via the actuator on the pivot point, is moved upwardly again and the clamping hook is opened. The actuator may comprise an operating rod which is pivotably on the pivot point of the clamping hook, and is in the main, orientated parallel to the first clamping hook arm. The operating rod may also be formed via a multi-part component to include, for example, a spindle with fork heads at the ends for articulation. A force in the pulling direction may be applied to the operating rod via a pneumatic cylinder and/or via an electric motor and/or via a hand lever. The force of the pneumatic cylinder, of the hand lever or of the electric motor in the pulling direction, may be applied to the operating rod via a lever mechanism for force transmission.
In accordance with embodiments, using the hook clamp, only the clamping hook or the hook element is to be guided through an opening of the component which is to be clamped, so a small opening is sufficient for this task. In the case of this design, the hook element may cover a greater distance, and even in the event of more inaccurate positioning or design of the component which is to be clamped, may reliably grip this and pull it with high, almost constant pulling force.
In accordance with embodiments, the force of the actuator, in combination with the force of the spring element, in this case effects a pulling force in two directions, specifically in the pulling direction on the one hand and additionally in a direction which is normal thereto (i.e. downwardly) for closing the hook.
In accordance with embodiments, the guiding position and/or the pre-tensioning position may be arranged in a transition region between the first clamping hook arm and the second clamping hook arm, i.e., in proximity to that end of the second clamping hook arm which merges into the first clamping hook arm, or in proximity to that end of the first clamping hook arm which merges into the second clamping hook arm.
In accordance with embodiments, a guide pin which is displaceably mounted in the elongated hole of a guide housing in a direction parallel to the pulling direction, may be arranged on the clamping hook at the guiding position between the pivot point and the hook element.
Embodiments will be illustrated by way of example in the drawings and explained in the description below.
As illustrated in
In accordance with embodiments, the pulling direction x is a rearward movement whereas the hooking direction y is a downward movement that is approximately perpendicular to the pulling direction x.
The clamping hook 1 comprises a first clamping hook arm 4 and a second clamping hook arm 5 which is approximately at a right angle to the first clamping hook arm 4. The hook element 2 is formed on a free end of the first clamping hook arm 4. The actuator 3 is to move the clamping hook 1 into the closed position. The actuator 3 is connected via a hinge connection to the second clamping hook arm 5 at a pivot point A located, for example, on the free end of the second clamping hook arm 5.
At a guiding position F which is located between the pivot point A and the hook element 2, the clamping hook 1 may be displaceably mounted in an elongated hole 6 in a direction parallel to the pulling direction x. For this purpose, the clamping hook 1 has a guide pin 12 arranged at the guiding position F. The elongated hole 6 is formed in a guide housing 13 of the hook clamp. The actuator 3 may be fastened to the guide housing 13.
As illustrated in
In accordance with embodiments, the clamping hook 1 is pre-tensioned against the pulling direction x via a bias mechanism such as, for example, a spring element 7, at a pre-tensioning position V between the pivot point A and the hook element 2. The spring element 7 may comprise a compression spring which in the main is orientated parallel to the first clamping hook arm 4.
In accordance with embodiments, the actuator 3 may comprise a multi-component design that includes operating rod 8 orientated parallel to the first clamping hook arm 4, and a pneumatic cylinder 9. The operating rod 8 is configured to transmit a force to the pivot point A of the clamping hook 1. The clamping hook 1 may be installed in the guide housing 13, with guide pin inserted, clamps and positions components due to a pulling movement.
The hook clamp operates in such a way that in the open position (e.g.,
When the hook clamp is in an open position, the clamping hook 1 is pushed forwardly against the pulling direction x, via the pneumatic cylinder 9 or the hand lever 10, assisted by the spring element 7. The guide pin 12 of the clamping hook 1 then reaches the end of the elongated hole 6 which is provided for the guide pin 12, and is subsequently pushed upwardly as far as a stop on the clamping hook 1, and thus, reaches the open position again.
As illustrated in
As illustrated in
The terms “coupled,” “attached,” or “connected” may be used herein to refer to any type of relationship, direct or indirect, between the components in question, and may apply to electrical, mechanical, fluid, optical, electromagnetic, electromechanical or other connections. In addition, the terms “first,” “second,” etc. are used herein only to facilitate discussion, and carry no particular temporal or chronological significance unless otherwise indicated.
Those skilled in the art will appreciate from the foregoing description that the broad techniques of the embodiments can be implemented in a variety of forms. Therefore, while the embodiments have been described in connection with particular examples thereof, the true scope of the embodiments should not be so limited since other modifications will become apparent to the skilled practitioner upon a study of the drawings, specification, and following claims.
Number | Date | Country | Kind |
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18163298 | Mar 2018 | EP | regional |
Number | Name | Date | Kind |
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6648316 | Vouland | Nov 2003 | B1 |
20040041323 | Migliori | Mar 2004 | A1 |
Number | Date | Country |
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206296615 | Jul 2017 | CN |
206296615 | Jul 2017 | CN |
69903316 | Jun 2003 | DE |
202004019099 | May 2005 | DE |
202015008208 | Jan 2016 | DE |
1683606 | Jul 2006 | EP |
2626174 | Aug 2013 | EP |
3095558 | Aug 2017 | EP |
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CN206296615 Reference Machine Translation (Year: 2017). |
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Number | Date | Country | |
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20190291245 A1 | Sep 2019 | US |