Patent Description:
A shackle is typically used for joining chains or for attaching blocks, hooks, rigs and the like to a chain, rope or wire. Shackles are found in many sizes and are intended for loads from a few kilos to several hundred tonnes.

A conventional shackle comprises a U-shaped shackle body and a shackle pin. The shackle body comprises a first end and an opposite second end, the first end and the second end being provided with corresponding cut-outs for the shackle pin.

The shackle pin comprises a first end and a second end, the first end being arranged to be passed through the corresponding cut-outs, and the second end being arranged to abut supportingly against an outside of the first end or the second end of the shackle body so that the shackle pin is locked in a first axial direction.

To lock the shackle pin in a second axial direction, it is known to fit a locking pin and/or a nut at the first end of the shackle pin. The patent document <CIT> discloses an example of such a solution. It is also known to provide the shackle pin with two externally threaded portions arranged to engage with two corresponding threaded portions at the first and second ends of the shackle body.

The patent document <CIT> discloses a shackle pin provided with an axial and helical groove arranged to engage with a corresponding guiding peg in one of the cut-outs of the shackle body. The shackle pin is locked by the peg and the groove rotating the shackle pin through <NUM> degrees during the last part of the insertion.

Patent document <CIT> discloses a spring loaded quick release pin and tubular receiver with a retainer pin configured to secure the quick release pin in a shackle, clevis, yoke or forked rod end. The receiver is welded to a shackle or cast with the shackle as a single body. One end of the quick release pin has aligned J slots that engage the retainer pin positioned in the receiver with a clockwise twist. The other end of the quick release pin has a cap and a spring loaded sleeve that biases the cross pin against outside of the second leg of the shackle. The spring bias keeps the short leg of the J slot engaged with the retaining pin. The quick release pin is removed with a push and counter clockwise twist. There is provided a kit with a receiver, a bushing and a quick release pin for installing or retrofitting existing shackles.

Patent document <CIT> discloses a latching arrangement, in particular for a component from lifting, lashing or fastening technology. The latching arrangement has a first component provided at its one end with at least one laterally protruding, spring-tensioned latching projection, and a second component provided with a receptacle configured to receive in an insertion direction and to fasten rotatably the end of the first component. The second component comprises a latching recess for the latching projection, wherein the latching recess is bounded at least at one side by a release shoulder displaceable into the latching recess which is provided with a hand switch arranged so as to be accessible from outside the latching arrangement, which hand switch is connected in a movement-transmitting manner to the release shoulder and closes the receptacle. By simple actuation of the hand switch, the latching can be repeatedly and easily released.

Patent document <CIT> discloses a releasably engageable locking pin for coupling members such as shackles. The locking pin comprises a shaft of noncircular cross-section with a head at one end. The noncircular shaft is engageable in aligned complementary apertures in shackle devises to prevent rotation of the pin in the apertures. At the end of the pin opposite the head is a bayonet-type coupling formation to releasably engage a retaining member under the influence of a resilient bias caused by axial compression of a resiliently deformable member when in a locked position.

Patent document <CIT> discloses a shackle comprising a pin rotatably mounted and moveable vertically in eyes formed in the outer ends of a substantially U-shaped member, a coiled spring arranged between the head of the pin and one of the ends of the member a projection on the pin, slots in the said eyes adapted to receive the projection, a sleeve moveably mounted on the pin and slidable in a handle formed on the head of the pin, the coiled spring being arranged within said handle, for the purposes described.

Patent document <CIT> discloses a quick and safe locking system and it is applicable whenever a pin needs to be locked longitudinally in a bore which is the case with tackle and mainly shackles. To this end, the locking system is made up of one or more metal parts which are housed in a groove made on the shaft, while a second groove, placed after the first, increases the safety of the system in such a way that, to insert the pin and lock it, only one translational movement is required, obtained by passing over its end, while unlocking takes place in at least two movements, one rotation, the other translation, thus making impossible any risk of accidental unlocking.

Patent document <CIT> discloses a locking pin system comprising a pin in the form of a shaft, and retaining assemblies at opposite ends of the shaft. The ends of the shaft are captively held in locating apertures of a lug of a shackle. The lug has aligned opposite recesses in which the retaining assemblies are fixed. The retaining assemblies each include a barrier locatable adjacent the respective locating aperture of the lug to close off the locating aperture, thereby preventing the shaft from being ejected through the locating aperture. The barrier includes a lock formation operable to engage a locating formation associated with the shackle to releasably lock the barrier in position.

Patent document <CIT> discloses a pin or bolt slidingly supportable in rings at opposite ends, or throughout its body in a sleeve, such as through the eyes of a clevis, is usefully locked against axial displacement by a radially sliding spring-biased detent which fits into a groove of a supporting ring or sleeve, securing it against axial displacement. The supporting ring has a slot extending inward from a support surface and sized to receive a key, such as a disc or a coin, which may be inserted in the slot to engage and depress the detent against its biasing spring, sufficient to displace it from the groove of the ring and thus unlocking and allowing the pin to be displaced in its support by sliding therefrom axially. In a modified form, where the supporting rings of a clevis are dimensioned so small that the radially cut slot would tend to weaken them, the ends of the pin may be secured by extra annular rings or washers mounted adjacent to the main supporting rings of the clevis. In the modified form the extra locking rings are sized to receive the internal groove for retaining the tip of the spring biased detent, as well as the slot cut radially into the additional ring, through which the key-like coin is inserted for radial displacement of the detent and thus releasing a locked pin for axial movement. In a second modification the key may be a small plate resiliently supported in a slot between resilient pads in a keyway groove cut in a clevis ring from which the outer end of the key extends, allowing a finger to be inserted to press against the key plate, pressing it against the tip of the detent for unlocking the pin for axial movement.

Patent document <CIT> discloses locking devices as well as methods of their manufacture and use. One locking device includes first and second legs operatively coupled together to form a perimeter substantially uninterrupted from a proximal end of the first leg to a proximal end of the second leg. The proximal ends are separated by an opening, and each proximal end respectively defines a passage. A keyway extends from the first leg passage, and first and second shoulders are adjacent the keyway. A receiving area extends from the second leg passage. A locking pin passes through the second leg passage and is movable between an open position, a closed position, and an intermediate position. The locking pin has a key and a stop that prevent the locking pin from passing entirely through the second leg passage. A biasing member biases the locking pin in various ways.

Patent document <CIT> discloses a shackle with captured pin assembly. The shackle includes a pair of opposed legs. A first ear for one of the opposed legs includes an opening therethrough to receive a shackle pin. A recess in the opening receives a spring clip surrounding a shaft of the shackle pin. A second ear for another of the opposed legs is opposed to the first ear. The second ear has an opening therethrough to receive the shackle pin and has an opening with a threaded portion. The shackle pin has a head, a threaded portion engageable with the threaded portion of the second ear opening, and a reduced diameter portion. The rotating retaining clip rotates about an axis parallel to the shackle pin between a locked and an unlocked position.

Patent document <CIT> discloses a safety lock for a removable shaft which has special utility when disposed on a clevis or like device. The lockable shaft is disposed by means which readily permit free lateral movement while preventing accidental disengagement under load bearing conditions when in the locked position. In an embodiment, shaft removal from a cooperating support member is prevented by a shaft restrictive means. Thus, complete removal of the shaft from support members during load transfer is avoided.

Patent document <CIT> discloses a locking pin and clevis wherein a slidable lockable member engages one end of the pin to lock it and a spring can be locked to said slide member to prevent it from moving to the unlocked position. The spring can be disengaged with the slide member to allow the slide member to be moved to the unlocked position so that the pin can be moved out of engagement with the one end of the clevis.

Patent document <CIT> discloses a shackle for preventing a screw-bolt from being loosened by reverse rotation. More specifically, a shackle for preventing a screw-bolt from being loosened by reverse rotation that can prevent a heavy object from falling on account of the separation of the screw-bolt from a shackle main body by reverse rotation, which is caused by continuous vibration or external impact when a hoist lifts the heavy object, by installing and using a rotation control device that prevents the reverse rotation of the screw-bolt. The shackle for preventing a screw-bolt from being loosened by reverse rotation comprises: a shackle main body having insertion holes formed in opposite sides thereof; a screw-bolt inserted into the insertion holes that are formed in the shackle main body; and a rotation control device that is fixedly coupled to the outside of the shackle main body and selectively restricts the rotational direction in which the screw-bolt is rotated by an external force.

Patent document <CIT> discloses a safety clasp for securely engaging a mechanical fastener, the safety clasp including a body, at least two primary engagement formations/members, and a tether-engaging component. The body defines a seat for receiving a mechanical fastener, the mechanical fastener is securable to a complementary fastening member. The primary engagement formations/members extend from the seat, for engaging the mechanical fastener. The tether-engaging component is rotatable relative to the body, for tethering the safety clasp to an anchor point external to, and separate from, the mechanical fastener.

Patent document <CIT> discloses a pinned connection assembly including a first rigging component, a second rigging component, a rigging pin, a locking pin, and a lock. The first rigging component has an end with at least one coupling aperture and at least one retention aperture that is transverse to the coupling aperture. The second rigging component has an end with at least one coupling aperture. The rigging pin has an end with a retention groove. The rigging pin is inserted through the coupling apertures of the first and second rigging components. The locking pin has an end with a locking groove. The locking pin is inserted through the retention aperture and the retention groove. The locking groove has guide, transitional, and locking portions for engaging a key of the lock.

In a conventional shackle, the shackle pin is releasable from the shackle body. Therefore, the shackle pin must be secured to the shackle body with a safety chain.

In major lifting operations, the shackle must often be connected above the body that is to be lifted, and there is often a person in the immediate vicinity of the coupling. An operation like that typically involves the shackle body hanging on a first rope, whereafter the operator must lift up and position a second rope in the shackle body, and at the same time fit the shackle pin into the shackle body. This operation is considered as critical in many cases and a more user-friendly and safer shackle is therefore sought.

The invention has for its object to remedy or reduce at least one of the drawbacks of the prior art or at least provide a useful alternative to the prior art.

The object is achieved through the features that are specified in the description below and in the claims that follow.

In a first aspect, the invention relates more specifically to a shackle lock for positioning on a shackle body, the shackle lock comprising a housing, at least one locking body and a displaceable sleeve which is displaceable in an axial direction of the housing. The housing is arranged to be connected to the shackle body and is arranged to house a first end of a shackle pin. The at least one locking body is arranged to engage with a peripheral locking groove at the first end of the shackle pin. The sleeve, in a locking position, is arranged to keep the at least one locking body in the groove, and is arranged, in a releasing position, to disengage the at least one locking body from the groove.

In an advantageous embodiment, the first end of the shackle pin which is described herein may have a circular cross section which corresponds to an internal circular cut-out in the housing. By a peripheral groove is understood, herein, a radial groove encircling the shackle pin.

The sleeve surrounds a portion of the housing. When the sleeve is in the first locking position, the at least one locking body is in an engaged position in the groove of the shackle pin when the shackle pin is positioned in the housing. The at least one locking body may be in the engaged position even when the shackle pin is not positioned in the housing.

To be able to move the shackle pin into the housing or out of the shackle lock, the at least one locking body must be released from the engaged position. The at least one locking body may be released from the engaged position by pulling the sleeve backwards in the axial direction of the housing, away from the shackle body.

In a first embodiment, the sleeve may be freely displaceable in a first axial direction and an opposite second axial direction. This gives a simple design of the shackle lock, in which the sleeve is slid manually between the locking position and the releasing position.

To prevent the freely displaceable sleeve from sliding unintendedly, the sleeve and the housing may comprise a device for keeping the sleeve in the locking position and/or the releasing position. Such a safety device may, for example, be an L-shaped, J-shaped or U-shaped guiding groove in the housing or sleeve, said guiding groove engaging with a corresponding guiding peg in the other one of the housing and sleeve. Thereby the sleeve must first be rotated before it can be displaced.

The effect of the shackle lock being self-locking is that the at least one locking body engages automatically with the groove, and that the sleeve is then moved automatically into the locking position when the shackle pin is positioned in the shackle lock. This simplifies the locking of the shackle pin and increases safety because the operator does not have to carry out an active action to position the at least one locking body in the engaged position. Such a locking of the shackle pin is referred to as a passive locking.

Unlike a passive locking, an active locking will typically include the use of separate locking elements such as a nut or a split-pin, or the use of a tool.

The shackle lock may be arranged to release the at least one locking body automatically when the shackle pin is being inserted into the shackle lock, in that the first end of the shackle pin comprises a cone arranged to force the at least one locking body outwards and thereby the sleeve backwards. When the cone has passed the at least one locking body, the at least one locking body will go into an engaged position so that the shackle pin cannot be pulled out. This principle is known to be used in hydraulic quick-release couplings, among other things.

The shackle lock may comprise a spring arranged to keep the sleeve in the locking position.

The effect of the spring is that the sleeve is biased into the locking position so that the at least one locking body is kept in the engaged position as long as the sleeve is not subjected to a force of opposite direction greater than the spring force, for example by the sleeve being pulled back by means of hand power.

When the shackle pin is to be released from the shackle lock, the sleeve is pulled away from the shackle body so that the at least one locking body is released and can be forced radially outwards when the shackle pin is pulled out of the shackle lock.

The sleeve may be kept in the locking position by means of a push force provided by a pressurized fluid. The fluid may be oil. The fluid may alternatively be a gas, typically air.

A hydraulic or pneumatic spring force may be relevant in larger locks, in which the dimensions of the shackle lock and the sleeve are so large that it may be difficult or impractical to operate the sleeve manually. The fluid pressure may, for example, be provided by means of a prior-art actuator. The actuator may be linear. The actuator may be a rotating one.

The at least one locking body may be a ball.

The effect of the at least one locking body being a ball is that the shackle lock may include a plurality of locking bodies which are radially movable between a releasing, outer position and an inner locking position. The solution with several balls as described herein is known to have been used in, for example, hydraulic quick-release couplings and is a proven and safe solution.

In an alternative embodiment, the at least one locking body may be an annular spring with an open portion, the annular spring being expandable from a smallest diameter to a largest diameter.

In a further alternative embodiment, the at least one locking body may be a bail adapted for radial displacement between a locking position and a releasing position. The bail may be spring-loaded into the locking position.

The shackle lock may comprise a threaded portion arranged to engage with a corresponding threaded portion of a shackle body.

The effect of a threaded connection as is described herein is that the shackle lock may be formed as a separate component for retrofitting to a shackle body with a corresponding threaded portion. Another advantage of a threaded connection is that the shackle lock may be replaced on possible wear or damage.

An advantageous threaded connection may comprise an externally threaded portion on the housing and a corresponding internally threaded portion in the shackle body. By the threaded portion of the shackle body being an internal one, the threaded portion of the shackle body may be formed without having to add a projecting portion to the shackle body.

In an alternative embodiment, the shackle lock may be adapted for permanent attachment to the shackle body. By permanent attachment may be understood, herein, that a portion of the shackle lock is attached to the shackle body by, for example, heat treatment or a press fit, and that said locking portion cannot be separated from the shackle body without the use of heat or a cutting tool.

In a further alternative embodiment, the housing of the shackle lock may be formed of a projecting portion belonging to the shackle body. The projecting portion may be formed as part of a moulding process for the shackle body.

The effect of the shackle lock being permanently attached to the shackle body is that a joining of the housing and shackle body which is stronger than a threaded connection may be provided. Further, machining of the inside of the housing may happen at the same time as holes for the shackle pin are machined in the shackle body.

In a second aspect, the invention relates more specifically to a shackle comprising a shackle body and shackle pin, and a shackle lock in accordance with the first aspect of the invention. The shackle lock is arranged on an outside of the first end of the shackle body, the shackle lock being arranged axially coincidingly with the cut-outs of the shackle body, and the shackle lock projecting from the first end of the shackle body in a direction away from the second end of the shackle body. The shackle pin is provided with a peripheral locking groove at a first end of the shackle pin, the peripheral locking groove being arranged to engage with at least one locking body belonging to the shackle lock.

By an outside may be understood, herein, a face comprising a cut-out for a shackle pin. The shackle lock is positioned on an outside of the first end.

The effect of a shackle comprising a shackle lock as is described herein is that a simpler and safer use of shackles than that of the prior art may be provided.

The shackle lock may be releasably attached to the shackle body. The shackle lock may be permanently attached to the shackle body.

By releasably attached may be understood, herein, that the shackle lock may be fitted to the shackle body and removed from the shackle body, for example via a threaded connection. The threaded connection may comprise an externally threaded portion on the shackle lock and an internally threaded portion in the shackle body. The externally threaded portion of the shackle lock may be formed in a housing belonging to the shackle lock.

The shackle may comprise a shackle pin with a peripheral locking groove at the first end of the shackle pin, the peripheral locking groove being arranged to engage with at least one locking body belonging to the shackle lock.

The effect of the peripheral locking groove is that the shackle pin can be locked in an axial direction without the use of separate locking means such as a locking pin or a nut.

The peripheral locking groove of the shackle pin may have a width arranged to give the locking body moving space in the axial direction of the shackle pin.

By width may be understood, herein, a recess in a radial direction of the shackle pin. Said moving space is achieved when the width of the groove is larger than the width of the locking body measured in the axial direction of the shackle pin.

An effect of the peripheral locking groove having a width arranged to give the locking body moving space in the axial direction of the shackle pin is that the shackle pin can be moved in a limited axial direction. In technical language, this movement is referred to as slack. Slack may be advantageous because it may help to transmit loads from the at least one locking body and groove to an abutment surface between the shackle pin and the shackle body.

By the shackle pin including the locking groove, a lockable shackle pin without any movable parts may be provided, as the movable parts for locking the shackle pin to the shackle are arranged in the housing. Thereby a shackle with a lockable shackle pin may be provided in which movable parts belonging to the lock, for example balls and springs, may be positioned in a protected manner inside the housing.

The shackle pin may include a recess with a first end arranged to engage with a corresponding stop at the second end of the shackle body, a shackle lock being arranged at the first end of the shackle body. The recess may be plane.

The effect of the recess is that the shackle pin cannot unintendedly be pulled out of the shackle body, and that it is only possible to pull the shackle pin out of the shackle lock when the flat of the recess is parallel to the stop. This gives an additional safety device for the shackle pin.

When the shackle is being used, a connected strap or a rope should rest against the curved surface of the shackle pin and as little as possible in the transition between the recess and the curved surface. Said transition is preferably rounded but may cause an undesired point load on straps and ropes. Therefore, in use, it is natural to orient the shackle pin in such a way that the flat of the recess faces in the direction of force of the strap or rope. In normal use, this direction will be perpendicular to the stop, so that the flat of the recess will not be parallel to the stop.

When fitting and removing the shackle pin, the stop may be removed.

In a second end, the shackle pin may comprise a radial recess adapted for rotatable engagement with the stop.

The effect of the radial recess is that the shackle pin may rotate around its centre axis when the peripheral locking groove of the shackle pin is in a locking engagement with the shackle lock. Further, when in engagement with the radial groove, the stop will give an extra axial locking of the shackle pin.

In a further aspect, the invention relates to a locking device for a shackle, the locking device comprising a shackle pin and a shackle lock in accordance with the first aspect of the invention, and at least one of a first safety function and a second safety function for the shackle pin:.

In what follows, examples of preferred embodiments are described, which are visualized in the accompanying drawings, in which:.

Reference is made first to <FIG>: A shackle lock <NUM> is positioned on the outside of a shackle body <NUM>, the shackle lock <NUM> comprising a housing <NUM>, at least one locking body <NUM> and a displaceable sleeve <NUM>, the housing <NUM> being arranged to house a first end <NUM> of a shackle pin <NUM>. The at least one locking body <NUM> is arranged to engage with a peripheral locking groove <NUM> at the first end <NUM> of the shackle pin <NUM>. The sleeve <NUM>, in a locking position (<FIG>, <FIG> and <FIG>), is arranged to keep the at least one locking body <NUM> in the groove <NUM>, and is arranged, in a releasing position (<FIG> and <FIG>), to release the at least one locking body <NUM> from the groove <NUM>. The shackle body <NUM>, shackle pin <NUM> and shackle lock <NUM> constitute a shackle <NUM>.

The shackle body <NUM> comprises a first end <NUM> and a second end <NUM> with axially coinciding cut-outs <NUM> adapted for the insertion of the shackle pin <NUM>. In a first embodiment, the shackle lock <NUM> is attached to the first end <NUM> via a threaded connection. The housing <NUM> comprises an outer threaded portion <NUM> arranged to engage with an internally threaded portion <NUM> at the first end <NUM> of the shackle body <NUM>.

In this embodiment, the shackle lock <NUM> comprises a housing <NUM>, an end cap <NUM>, a sleeve <NUM>, a first spring <NUM>, a second spring <NUM> and a plurality of locking bodies <NUM>, shown in the figures as balls.

The shackle pin <NUM> comprises a first end <NUM>, a coupling portion <NUM> and a second end <NUM>. The first end <NUM> and the coupling portion <NUM> are separated by a peripheral groove <NUM> arranged to receive at least one locking body <NUM>.

In one embodiment, the second end <NUM> of the shackle body <NUM> includes a recess for a stop <NUM> arranged to prevent the shackle pin <NUM> from being pulled out of the shackle body <NUM> by accident. In <FIG>, the stop <NUM> is shown as a tension pin. The stop <NUM> may be removed when the shackle pin <NUM> is being installed and removed.

The springs <NUM> and <NUM> push the sleeve <NUM> towards the shackle body <NUM>, so that an abutment surface <NUM> keeps the balls <NUM> in a position of engagement with the groove <NUM> belonging to the shackle pin <NUM>. When the shackle pin <NUM> is to be released, the sleeve <NUM> is pulled towards the end cap <NUM> so that the balls <NUM> can be disengaged and forced outwards by the shackle pin. The sleeve <NUM> is shown with a cone <NUM> arranged to push the balls <NUM> into the groove <NUM> when the shackle pin <NUM> is to be locked.

In <FIG> and <FIG>, a second threaded portion <NUM> between the housing <NUM> and the sleeve <NUM> is shown. The second threaded portion <NUM> is arranged to guide and keep the sleeve <NUM> in a retracted position as shown in <FIG>. It is pointed out that the threaded portion <NUM> shown in <FIG> and <FIG> is only illustrative and that real threads may be of a different design from the one shown in the figures.

<FIG> show an alternative embodiment of the shackle lock <NUM>, in which the housing <NUM>' is attached to the shackle body <NUM> by a press fit, the housing <NUM>' of the shackle lock <NUM> having been extended by an engagement portion <NUM> arranged to engage with a corresponding cut-out <NUM> in the shackle body <NUM>. Further, the housing <NUM>" is shown with a guiding groove <NUM> shaped like an L or a J, arranged to engage with a corresponding guiding peg <NUM> arranged in a radially inward-projecting manner on the sleeve <NUM> (see <FIG>).

<FIG> shows the housing <NUM>' with the guiding groove <NUM> and the sleeve <NUM> with the guiding peg <NUM>. When the sleeve <NUM> is pulled backwards and towards the end cap <NUM>, the guiding groove <NUM> and the guiding peg <NUM> will guide the sleeve first in an axial direction and then in a circumferential direction. When the guiding peg <NUM> has been moved to the end of the guiding groove <NUM>, the sleeve <NUM> will be kept in a releasing position so that the shackle pin <NUM> can be moved freely in and out of the shackle lock <NUM>'.

<FIG> shows a third embodiment of the shackle lock <NUM>, in which the housing <NUM>" is part of the shackle body <NUM>. Other components belonging to the shackle lock <NUM> are the same as those shown in the other figures.

<FIG> show the shackle pin <NUM> with a plane recess <NUM> with a first end <NUM> arranged to engage with the stop <NUM> shown in <FIG>. The shackle pin <NUM> is further shown with a radial recess <NUM> adapted for rotatable engagement with the stop <NUM>. The radial recess <NUM> makes it possible for the shackle pin <NUM> to rotate around its own axis. The radial recess <NUM> also functions as an additional safety device as the stop <NUM> will prevent axial movement of the shackle pin <NUM>, except when the shackle pin <NUM> is positioned in such a way that the plane recess <NUM> corresponds with the stop <NUM> as shown in <FIG>. For the shackle pin <NUM> to be releasable from the shackle lock <NUM>, the shackle pin <NUM> must have a radial position like the one shown in <FIG>. A person skilled in the art will understand that the recess <NUM> and the corresponding stop <NUM> are an advantageous embodiment, and not obligatory for the invention.

<FIG> shows an alternative embodiment of the shackle pin <NUM>', in which the peripheral locking groove <NUM>' is elongated in the axial direction of the shackle pin <NUM>, and the first end portion <NUM>' has a larger cone. The elongated locking groove <NUM>' and the coned end <NUM>' enable the shackle pin <NUM>' to engage self-lockingly with the shackle lock <NUM>.

The invention described herein can provide a locking device comprising the shackle pin <NUM> and the shackle lock <NUM>, and at least one safety function for the shackle pin <NUM>.

The at least one safety function may be a first safety function or a second safety function.

The first safety function may comprise the stop <NUM> positioned in the shackle body <NUM> and against the recess <NUM> of the shackle pin <NUM>, the first end <NUM> belonging to the recess <NUM> being arranged to engage with the stop <NUM> so that the shackle pin <NUM> is prevented from being pulled out of the shackle body <NUM>.

The second safety function may comprise the stop <NUM> and the radial recess <NUM> of the shackle pin <NUM>, the stop <NUM> being arranged to prevent axial movement of the shackle pin <NUM> when the shackle pin <NUM> is positioned in such a way that the recess <NUM> does not correspond with the stop <NUM>.

Claim 1:
A shackle lock (<NUM>) for positioning on a shackle body (<NUM>), wherein the shackle lock (<NUM>) comprises a housing (<NUM>, <NUM>', <NUM>"), at least one locking body (<NUM>) and a sleeve (<NUM>, <NUM>') which is displaceable in an axial direction of the housing (<NUM>, <NUM>', <NUM>"), wherein:
- the housing (<NUM>, <NUM>', <NUM>") is adapted for connection to the shackle body (<NUM>) and is arranged to house a first end (<NUM>, <NUM>') of a shackle pin (<NUM>);
- the at least one locking body (<NUM>) is arranged to engage with a locking groove (<NUM>, <NUM>') at the first end (<NUM>, <NUM>') of the shackle pin (<NUM>); and characterized in that
- the sleeve (<NUM>, <NUM>'), in a first locking position, is arranged to keep the at least one locking body (<NUM>) in the groove (<NUM>, <NUM>') and, in a releasing position, is arranged to release the at least one locking body (<NUM>) from the groove (<NUM>, <NUM>').