Patent Description:
Concrete is strong under compression but often has relatively weak tensile strength. Reinforcing bars, or rebars, are therefore often used to strengthen concrete structures, where they significantly increase the tensile strength of the concrete.

The most common type of rebar is carbon steel, typically consisting of hot-rolled round bars with deformation patterns. Other readily available types include stainless steel, and composite bars made of glass fibre, carbon fibre, or basalt fibre. The steel reinforcing bars may also be coated in an epoxy resin designed to resist the effects of corrosion mostly in saltwater environments, but also in land-based constructions.

The rebar elements are normally connected into a rebar structure or lattice by tying the elements together with steel wire. For tying epoxy coated or galvanised rebars, epoxy coated, or galvanized wire is normally used. The wire may also be coated in plastic or the like to prevent corrosion.

Due to the large number of connection points between rebar elements in a larger rebar structure, it is desired to automate the wire tying.

<CIT> discloses an automatic wire tying device for tying rebars together.

<CIT> describes a wire holding mechanism based on cooperating wheels. The wheels on one side of the wire are supported on a movable member, allowing release of the wire in an efficient manner.

<CIT> shows a wire tying device comprising a wire locking mechanism with toothed wheels. One of these toothed wheels are arranged one a type of excentre arm which can be operated to release the wire from the locking mechanism.

<CIT> shows a wire tying device with a wire locking mechanism comprising toothed wheels.

<CIT> describes a wire tying device with wheels that engage the wire. One of the wheels are arranged on the distal end of an arm that can be operated to release the wire from a locking position.

<CIT> describes a wire tying device with a wire locking mechanism based on opposing toothed wheels. One of the wheels are arranged on the distal end of an arm forming an acute angle relative to a holding plane of the mechanism.

<CIT> describes a wire locking mechanism based on a lever comprising a front part that is arranged to cooperate with a support to hold the wire in locking position.

It is important that the rebars are firmly connected together and that the wire knots are taut. Achieving a sufficiently tight knot may be a problem when using automatic wire tying devices, especially if the wire is slippery due to, e.g., water, ice and/or oil on the wire. A further problem relates to if the wire has an uneven thickness that varies along the wire length, since this complicates, e.g., calibrating an automatic wire tying device locking mechanism.

There is a need for improved automatic rebar wire tying devices.

It is an object of the present disclosure to provide improved automatic rebar wire tying devices. This object is at least in part obtained by a wire locking mechanism for a rebar wire tying device, as described in claim <NUM>. The locking mechanism comprises a holding member and a counter-holding member arranged to receive a free end of a wire and to engage respective sides of the wire to releasably hold the wire in a locking position, where a holding force exerted on the wire by the holding member is normal to a holding plane. The holding member is supported on a first end of an excentre arm. The excentre arm is rotatably supported on a first shaft to rotate about an excentre arm center of rotation, wherein the holding member is arranged distanced along a first axis from the excentre arm center of rotation, the first axis forming an acute angle with the holding plane when in the locking position, wherein the holding member comprises a first toothed wheel rotatably supported on a second shaft. This way even slippery wires are held firmly during knot formation. The excentre arm arrangement provides for an increased holding as the wire is pulled out from the locking mechanism. The wire can, however, be released in a controlled manner by separating the holding member from the counter-holding member.

The holding member of the wire locking mechanisms according to the invention comprises a catch arrangement configured to engage the first toothed wheel in locking contact to lock the first toothed wheel when in the locking position. Thus, the wire can be released in a precise manner, and there is a limited amount of build-up of wire shavings as the wire is released, since the wire does not shave against, e.g., a holding pad or the like.

According to aspects, the first toothed wheel comprises teeth with a circumferentially blunt and/or essentially flat portion configured to engage the wire when in the locking position. The circumferentially blunt and/or essentially flat portion reduces the risk of the wire braking during knot formation when the wire is held by the locking mechanism, since a blunt tooth does not cut into the wire in the way a more sharp tooth would.

According to aspects, the counter-holding member comprises a second toothed wheel rotatably supported on a third shaft. The teeth on the second toothed wheel increases the ability of the mechanism to hold on to wires of varying thickness. The acute angle can also be formed more aggressively due to the teeth on the second toothed wheel, since now two wheels with teeth hold the wire in the locked position. The second toothed wheel further reduces build-up of wire shavings.

According to aspects, the wire locking mechanism comprises a first actuator arranged to rotate the excentre arm about the excentre arm center of rotation in a first direction to separate the holding member from the counter-holding member when in a wire-infeed mode. This way the wire can more easily enter into locking contact with the holding member and the counter-holding member, thereby simplifying the tying operation.

According to aspects, the wire locking mechanism comprises a second actuator arranged to rotate the excentre arm about the excentre arm center of rotation in a second direction opposite to the first direction to move the holding member into the locking position. The second actuator allows for efficient control of the mechanism, in particular, the mechanism can be placed in locking position by means of the second actuator.

According to aspects, the first actuator and/or the second actuator comprises a solenoid device. A solenoid device is a cost-effective control means which can be controlled electrically by, e.g., a control unit.

According to aspects, the excentre arm and the counter-holding member are supported on a joining member, wherein the joining member is rotatably supported on a fourth shaft to rotate in relation to a locking mechanism body in response to a pull force acting on the wire. This way the resulting knot on the wire becomes tighter, since the locking mechanism is able to align with a pull force acting on the wire during the knot tying operation, thereby minimizing any bends on the wire which contribute negatively to knot tightness.

According to aspects, the wire locking mechanism also comprises a control arm arrangement. The control arm arrangement comprises an engagement surface for engaging a cylinder cam, whereby, upon rotation of the locking mechanism body to a pre-determined angle, the control arm arrangement is configured to release the catch arrangement, thereby placing the first toothed wheel in a free rolling condition and releasing the wire from the wire locking mechanism. The control arm arrangement with the cylinder cam allows for a very precise timing of the release operation. This precise timing simplifies knot formation and reduces risk of the wire braking when tying the knot. The precise timing allows for forming tight knots with minimum slack, which is an advantage.

According to aspects, the engagement surface for engaging the cylinder cam comprises a cylindrical roller configured to traverse the cylinder cam. The roller reduces friction, which is an advantage.

Also disclosed and forming part of the invention is a wire tying device comprising a wire locking mechanism according to the invention and a control unit, as defined in claim <NUM>.

The present invention will now be described in more detail with reference to the appended drawings, where.

<FIG> shows a wire tying device <NUM> for tying wire knots that secure a rebar structure. The wire tying device is arranged to feed <NUM> a free end of a wire out from an opening in a tying head <NUM> of the device. The wire is rolled prior to being fed out from the wire tying head <NUM>, and therefore assumes an arcuate form due to the rolling inside the tying head <NUM>. <CIT> discusses rolling wire such that it extends in an arcuate form when exiting a wire tying head. Rolling arrangements for rolling rebar tying wire will therefore not be discussed in more detail herein.

Herein, the wire has a free end. This is the end of the wire which is feed out from the tying head <NUM> and then received back in the tying head, not the end of the wire which is left on the wire spool or other wire storage means.

The wire extends along an arcuate path to encircle the rebars (not shown in <FIG>) which are to be tied together and is then received <NUM> back in the tying head <NUM>, where it is held by a wire locking mechanism which will be discussed in detail below.

The wire locking mechanism body comprised in the wire tying head <NUM> is then brought to rotate <NUM> about a wire tying head axis H, which rotation forms a knot on the wire. The wire tying device <NUM> is also arranged to cut the wire.

The whole process is automatically executed in sequence when the wire tying device is triggered by an operator using a trigger <NUM>. A length of wire is stored on a spool <NUM> comprised in a spool compartment <NUM> of the wire tying device. Thus, the wire tying device <NUM> allows for conveniently an efficiently tying together rebar structures.

A problem when tying rebars together is that the wire sometimes is hard to hold fixedly by the wire locking mechanism during formation of the knot. The wire may, e.g., be slick from oil, water, ice and the like, causing it to slip in the locking mechanism. Such slipping often results in a loose knot, which is not desired since too many loose knots lead to a non-rigidly assembled reinforcement structure. Also, slipping wires tend to cause build-up of wire particles inside the wire tying head, since the slipping wire shaves or is abraded by the locking mechanism as it slips.

Also, the wire must be released at the exact right time in the tying process, since otherwise the wire may brake at the wrong time, causing a failed knot. This is because tension forces in the wire increases during rotation <NUM> of the wire tying head. It may be a problem to achieve sufficient release timing accuracy.

<FIG> illustrates a wire locking mechanism <NUM> for a rebar wire tying device such as the device <NUM>. The locking mechanism comprises a holding member <NUM> and a counter-holding member <NUM> arranged to receive a free end of a wire <NUM> and to engage respective sides of the wire <NUM> to releasably hold the wire in a locking position. Normally, the holding member <NUM> and the counter-holding member <NUM> are arranged to engage opposite sides of the wire <NUM>, but this is not necessary as the holding member may engage the wire at an angle with respect to the counter-holding member.

To hold the wire <NUM> in locking position means that the wire is able to resist a pull force F2, pulling the wire out from the wire tying head, without significant slipping. The pull force F2 on the wire is generated, e.g., by running the wire feed mechanism of the wire tying device <NUM> in reverse.

A holding force F1 exerted on the wire <NUM> by the holding member <NUM> is normal to a holding plane A2 extending between holding surfaces <NUM>, <NUM> of the holding member and the counter-holding member.

To releasably hold the wire means that the holding force can be reduced at a pre-determined time instant during the tying process, whereby the wire is released from the wire locking mechanism.

Optionally, the holding surfaces <NUM>, <NUM> of any of the holding and/or counter-holding member comprises friction increasing means such as serrations or resilient coatings, e.g., rubber coating. The holding member <NUM> and/or the counter-holding member <NUM> may be arranged as toothed wheels, which will be discussed in detail below.

The holding member <NUM> is supported on a first end of an excentre arm <NUM>. The excentre arm <NUM> is rotatably supported on a first shaft <NUM> to rotate in direction R1 about an excentre arm center of rotation <NUM>. The holding member <NUM> is arranged distanced D along a first axis A1 from the excentre arm center of rotation <NUM>. This means that the holding force F1 develops as the excentre arm <NUM> is rotated about the excentre arm center of rotation <NUM> in counterclockwise direction when viewed as in <FIG>. The first axis A1 forms an acute angle A with the holding plane A2 when in the locking position.

The excentre arm <NUM> together with the holding member <NUM> and the counter-holding member <NUM> form an excentre locking mechanism which holds the wire in response to the pull force F2. If the pull force F2 increases, then the friction between the wire <NUM> and the holding member causes the excentre are <NUM> to want to rotate in direction R1 shown in <FIG>. This moment results in an increased holding force F1. Thus, the harder the wire is pulled - the more firmly it is held by the wire locking mechanism. Also, a reduced pull force F2 results in a reduced holding force F1. The wire locking mechanism can be opened, and the wire released, by rotating the excentre arm clockwise about the excentre arm center of rotation <NUM>, i.e., in a direction opposite to direction R1.

At least one of the holding member <NUM> and the counter-holding member <NUM> comprises a rotatably supported toothed wheel (illustrated in <FIG> by dashed circles). This at least one toothed wheel allows for holding wires of varying dimension, and also allows for releasing the wire without shaving material off from the wire, due to the rotation of the wheel.

In case only one of the holding member <NUM> and the counter-holding member <NUM> comprises a rotatably supported toothed wheel, the other may comprise, e.g., a supporting surface or the like. A holding member <NUM> not comprising a rotatably supported toothed wheel may be integrally formed with the excentre arm <NUM>, i.e., a portion of the excentre arm <NUM>.

<FIG> shows an example embodiment of the wire locking mechanism <NUM>. The holding member here comprises a first toothed wheel <NUM> rotatably supported on a second shaft <NUM>, and a catch arrangement <NUM> configured to lock the first toothed wheel when in the locking position. The catch arrangement <NUM> is supported on the excentre arm <NUM> and therefore rotates together with the first toothed wheel <NUM>.

According to aspects, the counter-holding member <NUM> comprises a second toothed wheel rotatably supported on a third shaft <NUM>. However, it is appreciated that the counter-holding member <NUM> may also comprise, e.g., a heel, block, or other fixed support.

A further catch arrangement can of course also be arranged to lock the second toothed wheel <NUM> so that there is one catch arrangement arranged per toothed wheel.

The teeth on the second toothed wheel increases the ability of the mechanism to hold on to wires of varying thickness along the wire length. The angle A, shown in, e.g., <FIG>, can be formed more aggressively due to the teeth on the second toothed wheel, since now two wheels with teeth hold the wire in the locked position.

With reference to <FIG>, an opening between the holding member <NUM> and the counter-holding member <NUM> can be created by rotating the excentre arm <NUM> in a direction opposite to the rotation direction R1. The wire <NUM> can then be received between the holding member and the counter-holding member more easily.

Optionally, the catch arrangement <NUM> is spring loaded towards a position to lock the first toothed wheel.

The second toothed wheel <NUM> making up the counter-holding member may be free-rolling, but as long as the catch arrangement <NUM> is in locking contact with the first toothed wheel <NUM>, and the wire <NUM> contacts both the first and the second toothed wheel, the locking mechanism <NUM> is in locking position. A holding force F1 will develop in response to a pull force F2 on the wire to hold the wire firmly even if the wire is slippery due to, e.g., oil or ice.

According to aspects, the first toothed wheel <NUM> comprises teeth with a circumferentially blunt and/or essentially flat portion <NUM> configured to engage the wire <NUM> when in the locking position. The blunt portions spare the wire from the cutting or shearing force exerted by the teeth on the toothed wheel on the wire when the holding force F1 is developed.

According to some aspects, the length of the teeth on the second wheel <NUM> is set in dependence of the wire thickness so as to not accidentally cut the wire by the holding force F1.

The different components of the wire locking mechanism may be spring loaded so as to be biased towards respective default positions. The spring biasing may be achieved using, e.g., torsion springs. For instance, the excentre arm <NUM>, <NUM> may be spring loaded towards the locking position and the catch arrangement <NUM> may be spring loaded towards a locking contact with the first toothed wheel <NUM>.

Alternatively, or in combination, the catch arrangement may be spring loaded towards a locking contact with the second toothed wheel <NUM>. It is again appreciated that any of the first and second toothed wheel, or both, can be arranged to be locked by a catch arrangement. There may be one, two, or more catch arrangements configured to lock toothed wheels when in the locking position.

In general, to operate the wire locking mechanisms <NUM>, <NUM>, the wire locking mechanism optionally comprises a first actuator arranged to rotate the excentre arm <NUM>, <NUM> about the excentre arm center of rotation <NUM>, <NUM> in a first direction (opposite to direction R1 in <FIG> and <FIG>) to separate the holding member <NUM>, <NUM> from the counter-holding member <NUM>, <NUM> when in a wire-infeed mode.

The wire locking mechanisms <NUM>, <NUM> optionally also comprise a second actuator arranged to rotate the excentre arm <NUM>, <NUM> about the excentre arm center of rotation <NUM>, <NUM> in a second direction R1 opposite to the first direction to move the holding member <NUM>, <NUM> into the locking position.

The first actuator and/or the second actuator may, e.g., comprise respective solenoid devices configured to exert forces F3, F4 on the excentre arm. <CIT> discusses such actuators. However, other actuators, such as actuators based on magnetic force, may also be used to control the wire locking mechanism.

A control arm arrangement <NUM> shown in <FIG> may be used to both engage and release the catch arrangement <NUM>, as will be discussed in more detail below in connection to <FIG>. The control arm arrangement <NUM> may also be used to force the excentre arm <NUM> to rotate in direction R1 towards the locking position. A solenoid device may be used to push onto the control arm arrangement, i.e., to exert a force F4.

It is, as noted above, preferred to release the wire from the wire locking mechanism with accurate timing so as to not break the wire during the tying operation. <FIG> shows details of a wire locking mechanism <NUM> which comprises a control arm arrangement <NUM>. The control arm arrangement <NUM> comprises an engagement surface <NUM> for engaging a cylinder cam <NUM>, whereby, upon rotation of the locking mechanism body <NUM> (shown in <FIG>) to a pre-determined angle. The control arm arrangement <NUM> is configured to release the catch arrangement <NUM>, thereby placing the first toothed wheel <NUM> in a free rolling condition and releasing the wire <NUM> from the wire locking mechanism.

With reference to <FIG> and <FIG>, the cylinder cam <NUM> allows for a precise control of the release of the wire locking mechanism <NUM>. By varying the cam width W1, W2, the pushing force F4 on the control arm arrangement <NUM> can be accurately synchronized with a rotation of the locking mechanism body during tying operation. The locking mechanism body <NUM> starts in a position where the cam width W1 is relatively small and therefore exerts no force <NUM> on the control arm arrangement <NUM>. As the locking mechanism body rotates, the width increases up to a width W2, and the control arm arrangement then moves in direction of the catch arrangement <NUM> to release the catch, thereby releasing the first toothed wheel <NUM>.

It is an advantage that the first and second toothed wheels are in free rolling condition as the wire is released, since this minimizes abrasion by the holding members on the wire <NUM>, thereby preventing build-up of wire particles inside the wire tying head <NUM>.

According to some aspects, the engagement surface <NUM> for engaging the cylinder cam <NUM> comprises a cylindrical roller configured to traverse the cylinder cam <NUM>. The roller reduces friction and therefore provides for a smoother knot tying operation. In other words, the control arm arrangement <NUM> comprises an engagement surface <NUM>, which may be a roller bearing. The control arm <NUM> is pivotably arranged about an axis <NUM>.

It is important that the wire <NUM> is not subject to an unnatural arcuate form during the tying operation, as this may result in a loose knot. With reference to <FIG>, such an arcuate form may result if the pull force F2 on the wire <NUM> is not aligned with the holding plane A2. With reference to <FIG>; To reduce this effect, the wire locking mechanism may be arranged rotatable with respect to the locking mechanism body <NUM>. This way, the whole locking mechanism will respond to a pull force on the wire by rotating R2 the holding plane A2 to be more aligned with the direction of a pull force F2. The wire locking mechanism may be spring-loaded towards a default position for receiving the wire.

Having this in mind, <FIG> schematically illustrate a wire locking mechanism <NUM>, <NUM> according to some aspects of the present invention. The excentre arm <NUM> and the counter-holding member <NUM> are supported on a joining member <NUM>, <NUM>, wherein the joining member <NUM>, <NUM> is rotatably supported on a fourth shaft <NUM>, <NUM> to rotate in relation to a locking mechanism body <NUM> in response to a pull force F2 acting on the wire <NUM>. It is appreciated that this rotating feature is applicable also to the more general locking mechanism <NUM> illustrated in <FIG>.

<FIG> is a flow chart illustrating a method and a control unit <NUM> configured to perform the method. The control unit <NUM> is configured to control a wire locking mechanism <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM> for a rebar wire tying device <NUM>.

With reference to <FIG>, the control unit is configured to transition S1 the wire locking mechanism from a neutral position P1 into a wire infeed mode position P2. As discussed above, the wire locking mechanism may be spring-loaded or otherwise biased towards a neutral position P1 shown in <FIG> where the excentre arm <NUM> is rotated to separate the holding member <NUM> from the counter-holding member <NUM>, and the catch arrangement is in locking contact with the first toothed wheel.

The control unit then controls S2 wire feed by the wire tying device <NUM> to receive a wire <NUM> in the wire locking mechanism <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM>. The wire is rolled prior to exiting the wire tying head, and therefore encircles the rebars to be tied together. <FIG> illustrates the wire locking mechanism in wire-infeed mode P2. The excentre arm <NUM> is rotated by means of, e.g., a solenoid device acting on a link arm <NUM> to generate the force F3. Note that the catch arrangement <NUM> is released when the locking mechanism is in the wire-infeed mode P2. This release can be achieved, e.g., by means of the control arm <NUM> discussed above. The wire <NUM> is able to enter between the holding member <NUM> and the counter-holding member <NUM> easily due to the free-rolling state of the toothed wheels in the wire-infeed mode P2.

The control unit then transitions S3 the wire locking mechanism from the wire infeed mode P2 into a locking position P3, where the wire is held between the holding member <NUM> and the counter-holding member <NUM>. To transition the locking mechanism into the locking position P3, the excentre arm <NUM> is caused to rotate in direction R1 by means of, e.g., the solenoid device and the control arm discussed above.

The locking mechanism then rotates in direction R2 in response to a pull force on the wire <NUM>. The pull force on the wire is generated by running the wire feed mechanism of the wire tying device in reverse. This rotation helps ensure that the knot is tight.

<FIG> shows a locking mechanism in rotated mode P4, after rotating in direction R2. The first axis A1 after rotation is denoted A1' and the holding plane after rotation is denoted A2'.

The control unit then rotates S4 <NUM> the locking mechanism body <NUM> to tie a knot on the wire <NUM> and, at a pre-determined angle of rotation, the wire is released S5 from the wire locking mechanism.

Many of the features disclosed above may be implemented independently from each other, as long as these implementations fall within the scope of the invention, which is only defined by the appended claims. For instance, with reference mainly to <FIG>, there is also disclosed herein, and not forming part of the invention, a wire locking mechanism <NUM>, <NUM> for a reinforcement bar, rebar, wire tying device <NUM>, the locking mechanism comprising a holding member <NUM>, <NUM> and a counter-holding member <NUM>, <NUM> arranged to engage respective and opposite sides of a wire <NUM> to releasably hold the wire in a locking position, where a holding force F1 exerted on the wire <NUM> by the holding member <NUM>, <NUM> is normal to a holding plane A2, wherein the holding member <NUM>, <NUM> is supported on a first end of an excentre arm <NUM>, <NUM>, the excentre arm <NUM>, <NUM> being rotatably supported on a first shaft <NUM>, <NUM> to rotate R1 about an excentre arm center of rotation <NUM>, <NUM>, wherein the holding member <NUM>, <NUM> is arranged distanced D along a first axis A1 from the excentre arm center of rotation <NUM>, <NUM>, the first axis A1 forming an acute angle A with the holding plane A2 when in the locking position, wherein the excentre arm <NUM>, <NUM> and the counter-holding member <NUM>, <NUM> are supported on a joining member <NUM>, <NUM>, wherein the joining member <NUM>, <NUM> is rotatably supported on a fourth shaft <NUM>, <NUM> to rotate in relation to a locking mechanism body <NUM> in response to a pull force F2 acting on the wire <NUM>.

With reference mainly to <FIG>, there is furthermore disclosed herein, and not forming part of the invention, a wire locking mechanism <NUM>, <NUM> for a reinforcement bar, rebar, wire tying device <NUM>, the locking mechanism comprising a holding member <NUM>, <NUM> and a counter-holding member <NUM>, <NUM> arranged to engage respective and opposite sides of a wire <NUM> to releasably hold the wire in a locking position, where a holding force F1 exerted on the wire <NUM> by the holding member <NUM>, <NUM> is normal to a holding plane A2, wherein the holding member <NUM>, <NUM> is supported on a first end of an excentre arm <NUM>, <NUM>, the excentre arm <NUM>, <NUM> being rotatably supported on a first shaft <NUM>, <NUM> to rotate R1 about an excentre arm center of rotation <NUM>, <NUM>, wherein the holding member <NUM>, <NUM> is arranged distanced D along a first axis A1 from the excentre arm center of rotation <NUM>, <NUM>, the first axis A1 forming an acute angle A with the holding plane A2 when in the locking position, the wire locking mechanism <NUM>, <NUM>, <NUM>, <NUM> further comprising a control arm arrangement <NUM>, the control arm arrangement <NUM> comprising an engagement surface <NUM> for engaging a cylinder cam <NUM>, whereby, upon rotation of the locking mechanism body <NUM> to a pre-determined angle, the control arm arrangement <NUM> is configured to release the wire <NUM> from the wire locking mechanism <NUM>, <NUM>.

Other example features disclosed above which may be implemented independently from each other, and not forming part of the invention, comprise a wire locking mechanism <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM> for a reinforcement bar, rebar, wire tying device <NUM>, the locking mechanism comprising a holding member <NUM>, <NUM> and a counter-holding member <NUM>, <NUM> arranged to engage respective sides of a wire <NUM> to releasably hold the wire in a locking position, wherein the holding member <NUM>, <NUM> and the counter-holding member <NUM>, <NUM> are supported on a joining member <NUM>, <NUM>, wherein the joining member <NUM>, <NUM> is rotatably supported on a fourth shaft <NUM>, <NUM> to rotate in relation to a locking mechanism body <NUM> in response to a pull force F2 acting on the wire <NUM>.

According to aspects, a holding force F1 exerted on the wire <NUM> by the holding member <NUM>, <NUM> is normal to a holding plane A2, wherein the holding member <NUM>, <NUM> is supported on a first end of an excentre arm <NUM>, <NUM>, the excentre arm <NUM>, <NUM> being rotatably supported on a first shaft <NUM>, <NUM> to rotate R1 about an excentre arm center of rotation <NUM>, <NUM>, wherein the holding member <NUM>, <NUM> is arranged distanced D along a first axis A1 from the excentre arm center of rotation <NUM>, <NUM>, the first axis A1 forming an acute angle A with the holding plane A2 when in the locking position.

According to the invention, the holding member <NUM> comprises a first toothed wheel supported on a second shaft <NUM>, and a catch arrangement <NUM> configured to engage the first toothed wheel in locking contact to lock the first toothed wheel when in the locking position.

According to aspects, the catch arrangement <NUM> is spring loaded towards a position to lock the first toothed wheel.

According to aspects, the first toothed wheel comprises teeth with a circumferentially blunt and/or essentially flat portion <NUM> configured to engage the wire <NUM> when in the locking position.

According to aspects, the counter-holding member <NUM> comprises a second toothed wheel rotatably supported on a third shaft <NUM>.

According to aspects, the excentre arm <NUM>, <NUM> is spring loaded towards the locking position.

According to aspects, the wire locking mechanism comprises a first actuator arranged to rotate the excentre arm <NUM>, <NUM> about the excentre arm center of rotation <NUM>, <NUM> in a first direction to separate the holding member <NUM>, <NUM> from the counter-holding member <NUM>, <NUM> when in a wire-infeed mode.

According to aspects, the wire locking mechanism comprises a second actuator arranged to rotate the excentre arm <NUM>, <NUM> about the excentre arm center of rotation <NUM>, <NUM> in a second direction opposite to the first direction to move the holding member <NUM>, <NUM> into the locking position.

According to aspects, the excentre arm <NUM>, <NUM> and the counter-holding member <NUM>, <NUM> are supported on a joining member <NUM>, <NUM>, wherein the joining member <NUM>, <NUM> is rotatably supported on a fourth shaft <NUM>, <NUM> to rotate in relation to a locking mechanism body <NUM> in response to a pull force F2 acting on the wire <NUM>.

According to aspects, the wire locking mechanism comprises a control arm arrangement <NUM>, the control arm arrangement <NUM> comprising an engagement surface <NUM> for engaging a cylinder cam <NUM>, whereby, upon rotation of the locking mechanism body <NUM> to a pre-determined angle, the control arm arrangement <NUM> is configured to release the catch arrangement <NUM>, thereby placing the first toothed wheel <NUM> in a free rolling condition and releasing the wire <NUM> from the wire locking mechanism.

According to aspects, the engagement surface <NUM> for engaging the cylinder cam <NUM> comprises a cylindrical roller configured to traverse the cylinder cam <NUM>.

According to aspects, the wire locking mechanism <NUM>, <NUM>, <NUM>, <NUM> comprises a catch arrangement configured to lock the second toothed wheel when in the locking position.

There is also disclosed herein, and not forming part of the invention, a wire locking mechanism <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM> for a reinforcement bar, rebar, wire tying device <NUM>, the locking mechanism comprising a holding member <NUM>, <NUM> and a counter-holding member <NUM>, <NUM> arranged to engage respective sides of a wire <NUM> to releasably hold the wire in a locking position, wherein the holding member <NUM> comprises a first toothed wheel supported on a second shaft <NUM>, and a catch arrangement <NUM> configured to lock the first toothed wheel when in the locking position, the locking mechanism further comprising a control arm arrangement <NUM>, the control arm arrangement <NUM> comprising an engagement surface <NUM> for engaging a cylinder cam <NUM>, whereby, upon rotation of the locking mechanism body <NUM> to a pre-determined angle, the control arm arrangement <NUM> is configured to release the catch arrangement <NUM>, thereby placing the first toothed wheel <NUM> in a free rolling condition and releasing the wire <NUM> from the wire locking mechanism.

Claim 1:
A wire locking mechanism (<NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM>) for a reinforcement bar, rebar, wire tying device (<NUM>), the locking mechanism comprising a holding member (<NUM>, <NUM>) and a counter-holding member (<NUM>, <NUM>) arranged to receive a free end of a wire (<NUM>) and to engage respective sides of the wire (<NUM>) to releasably hold the wire in a locking position, where a holding force (F1) exerted on the wire (<NUM>) by the holding member (<NUM>, <NUM>) is normal to a holding plane (A2), wherein the holding member (<NUM>, <NUM>) is supported on a first end of an excentre arm (<NUM>, <NUM>), the excentre arm (<NUM>, <NUM>) being rotatably supported on a first shaft (<NUM>, <NUM>) to rotate (R1) about an excentre arm center of rotation (<NUM>, <NUM>), wherein the holding member (<NUM>, <NUM>) is arranged distanced (D) along a first axis (A1) from the excentre arm center of rotation (<NUM>, <NUM>), the first axis (A1) forming an acute angle (A) with the holding plane (A2) when in the locking position, whereby the holding member (<NUM>) comprises a first toothed wheel rotatably supported on a second shaft (<NUM>), characterized in that the holding member (<NUM>) comprises a catch arrangement (<NUM>) configured to engage the first toothed wheel (<NUM>) in locking contact to lock the first toothed wheel when in the locking position.