The invention relates to a coil of cutting wire for a vegetation cutting machine, a cutting assembly comprising a cutting head and such a coil, and a process of manufacturing such a coil.
Self-supporting coils of cutting wire for vegetation cutting machines are of great interest since they render the insertion and/or replacement of the wire in a cutting head very easy.
In the present text, “self-supporting” means that the wire is capable of remaining coiled on itself, without any holding means external thereto. It is therefore not necessary to lock the turns of the coil by a binding surrounding its turns so as to hold them adjacent, nor by packaging adjusted to the dimensions and format of the coil.
The locking of the turns is temporary, i.e. intended to be effective during storage and shipment of the coil, until its insertion into the cutting head; however, the turns are separable under the effect of a pulling force exerted on the free end of the wire.
Document FR 2 967 548 discloses such a self-supporting coil, which is made of a wire having reciprocal retention provisions such that, when the wire is wound upon itself, each turn cooperates with at least one adjoining turn so as to retain it mechanically.
This wire therefore makes it possible in particular to make a self-supporting coil having a flat shape with a central void.
Such a self-supporting coil can be advantageously used in combination with a cutting head as described in document WO 2014/020178. Said cutting head includes:
When a user wants to insert the self-supporting coil in the cutting head, he merely has to open the cutting head, arrange the central void of the coil around the mandrel, reel off a given length of the wire to extend from the peripheral opening, and close the cutting head.
However, despite attempts to design the reciprocal retention arrangements so as to firmly hold each turn with respect to the other ones, the applicant has found that, under the effect of the centrifugal force, the turns may slide along each other in such a way that the coil tightens up around the mandrel.
A consequence is that the coil is difficult to remove from the cutting head when the user has to replace it with a new coil, because the user has to exert an extraction force that is greater than the insertion force.
In order to avoid such a tightening up of the coil, the cutting head may comprise specific embodiments intended to block the wire and limit the relative sliding of the turns.
For example, as described in document WO 2014/020178, the cutting head may be provided with a locking device for the wire at the peripheral opening. For example, this locking device can have a stud pivoting between a position that frees the wire when the head is not moving and a position locking the wire under the influence of centrifugal force when the head is driven in rotation by the motor. By locking the wire at the opening, the device should thus prevent the turns from sliding along one another under the influence of centrifugal force in the event that the turns are not firmly enough bonded together.
Another possibility described in document WO 2014/020178 is to provide the cutting head with a supporting plate applied onto the coil and that has a rough surface intended to prevent the turns from sliding along one another.
However, despite these arrangements, a certain sliding of the turns along one another is still observed, leading to a tightening up of the coil around the mandrel. As a result, the used coil may be difficult to remove from the mandrel.
Besides, a certain number of cutting heads on the market are provided with a “tap and go” system which makes it possible, after a simple tap against the ground by the lower portion of the cutting head, to automatically reel off a predetermined length of cutting wire, while the machine is operating.
In order to allow such an automatic reeling off of the cutting wire, the bonding strength between the adjacent turns should be minimal; otherwise, the outermost turns would remain attached to one another and the cutting wire could not be paid out of the cutting head.
However, the applicant has found that, irrespective of whether the turns are bonded by reciprocal arrangements as in document FR 2 967 548 or by adhesion as in document U.S. Pat. No. 4,024,635, with such a low bonding strength, the turns may slide along each other under the effect of the centrifugal force, in such a way that the coil tightens up around the mandrel.
A goal of the invention is to remedy to the above-mentioned drawbacks of the existing devices and to render easier the removal of a used coil from the mandrel.
Accordingly, the invention provides a coil of cutting wire for a vegetation cutting machine, wherein the wire is coiled on itself so as to form at least two temporarily bonded turns and a central void, characterized in that at least a part of the innermost turn of the coil is welded to the most adjacent turn.
The innermost turn is welded to the most adjacent turn over an angular sector comprised between 90° and 360°.
According to an embodiment, the innermost turn comprises, on its surface facing the central void, a plurality of grooves.
According to an embodiment, the coil has a flat shape.
Advantageously, the wire is made of a material comprising a polyamide and/or a copolyamide.
The cross section of the wire typically has an area equal to the cross-section of a round wire having a diameter comprised between 1.35 and 4 mm.
According to an embodiment, the coil comprises a plurality of temporarily bonded turns of at least two cutting wires, in particular between four and six cutting wires, bonded longitudinally in a separable fashion.
According to an embodiment, the wire comprises reciprocal retention arrangements so that each turn cooperates with at least one adjacent turn so as to hold it mechanically.
According to an embodiment, the turns are temporarily bonded by adhesion.
According to an embodiment, the turns are temporarily bonded by controlled partial fusion of the material of the wire.
Another object of the invention is a cutting assembly for a vegetation cutting machine such as a border trimmer or a brush cutter, comprising a coil as described above and a cutting head comprising:
Another object of the invention is a process of manufacturing a coil as described above. This process comprises the following steps:
According to an embodiment, the welding step further comprises applying a radially outwards pressure onto the innermost turn.
According to an embodiment, the welding step comprises forming a plurality of grooves on the surface of the innermost turn facing the central void.
Other features and advantages of the invention will be apparent from the detailed description that follows, based on the appended drawings wherein:
As illustrated in
By “temporarily bonded” is meant that the bonding strength of the turns is sufficient to have a self-supporting coil, but that the turns can be separated without damaging the wire under the effect of a pulling force exerted on the free end of the wire in view of reeling off a given length of the wire.
According to an embodiment, the wire 20 may comprise reciprocal retention arrangements (see
According to an embodiment, the reciprocal retention arrangements comprise a male element 201 and a female element 202 extending over all or part of the length of the wire 20, the male element 201 being adapted to penetrate the female element 202 when the wire 20 is coiled on itself so as to form a coil that may be either substantially flat, substantially cylindrical or substantially conical. Advantageously, the female and male elements are chosen so that the wire can be produced by conventional drawing/extrusion techniques.
For example, the male element may be a rib 201 extending over all or part of the length of the wire, while the female element 202 may be a groove extending so as to match the rib. If it is intended to form a flat coil, the rib 201 and the groove 202 preferably extend on opposite longitudinal sides of the wire. In general terms, the shape and dimensions of the rib 201 are adjusted to the shape and dimensions of the groove 202, so that the rib 201 can fit and be held with a suitable force in the groove 202 of an adjacent turn when the wire 20 is coiled on itself so as to form the coil. Preferably, the shape and dimensions of the rib 201 and groove 202 are chosen so that the rib 201 forcibly penetrates the groove 202 in the adjacent turn, with elastic deformation of the wire in the areas 203, when the wire 20 is coiled on itself. In this case, the elastic return of the material of the wire in these areas 203 ensures the holding of the rib 201 and groove 202 once engagement has been effected.
The wire 20 can be uncoiled by extracting the rib 201 from the groove 202. To this end, it suffices to pull with the fingers on the free end of the wire 20 so that the rib 202 causes the lateral walls 203 of the groove 201 to separate.
Alternatively, the turns can be temporarily bonded together by adhesion (for example by means of a chemical or thermal adhesive deposited continuously or discontinuously) between the turns, by localized partial fusion of the material of the cutting wire between two adjoining turns; by ultrasonic or friction welding. In this regard, one may refer to the techniques described in document U.S. Pat. No. 4,024,635.
Any other temporary connection means, that is allowing the turns to be held then separated without damaging the cutting wire, can be used without thereby departing from the scope of the present invention.
A first end 220 of the wire is located within the inner void of the coil, while the second end is a free end designed to emerge from the cutting head.
The cutting wire is made by extrusion of a thermoplastic material through a die defining the shape of the reciprocal retention arrangements.
The thermoplastic material typically comprises a polyamide and/or a copolyamide.
The cutting wire may be made by coextrusion of two or more different thermoplastic materials, e.g. a first material forming a core of the cutting wire and a second material forming a sheath surrounding at least partially the core.
The cross section of the wire has an area equal to the cross-section of a round wire having a diameter comprised between 1.35 and 4 mm, preferably between 1.35 and 2 mm.
The cross section may have any suitable shape providing sufficient contact surfaces between adjacent turns so as to allow a temporary bonding of the turns by adhesion, welding, or mechanical retention. For example, the cross section of the wire may be circular or have any convex polygonal shape (e.g. square, rectangular, triangular, hexagonal, etc.), or be inscribed in one of such shapes.
Once the cutting wire has been wound to form the self-supporting coil as shown in
Such a welding may be made by applying heat—and also preferably a radial outwards force—onto the innermost turn and the adjacent turn so as to provoke melting of the thermoplastic material.
Preferably, the innermost turn is welded to the directly adjacent turn over an angular sector of 360°. However, a smaller angular sector may be accepted, e.g. an angular sector of 90° or 180°.
During this operation, the first end 220 of the cutting wire may also be pressed onto the adjacent turn and adopt a flattened shape.
Possibly, more than the two above-mentioned turns may be welded. For example, the turn directly adjacent to the innermost turn may also be welded, on its outer side, to the directly adjacent turn.
In
As compared to the reciprocal retention arrangements, adhesive or other appropriate means that temporarily bind the turns, the welding can be considered as a permanent bonding of the innermost turn and the directly adjacent turns, meaning that these turns are not intended to be separated.
The welding has the effect of blocking both turns relative to each other, which thus prevents any relative sliding of these turns. As a consequence, even if such a sliding occurs with the turns that are only temporarily bonded by the reciprocal retention arrangements, adhesive or other appropriate means, it does not propagate to the innermost turn and thus does not lead to a tightening up of the coil around the mandrel.
Thus, even after significant use, the coil can still be removed easily from the mandrel.
According to an embodiment, the welding step can also comprise shaping the surface of the innermost turn facing the central void so as to form a plurality of grooves 230 therein (see
The coil 2 is set in a recess provided in a body 10 of the cutting head 1. A cover 30 intended to be secured to the body 10 closes the recess. In the embodiment illustrated in
The body 10 includes at least one opening 12a, 12b which opens into the recess in order to allow the emergence of a length of cutting wire separated from the coil. The openings 12a, 12b are preferably evenly distributed circumferentially; for example, if the openings are two in number, they are advantageously diametrically opposite. Naturally, if more wires are to be used in the cutting head, a sufficient number of openings will be provided.
Moreover, all the openings are not necessarily arranged on the body 10 as illustrated in
According to an embodiment, the inner and outer walls of the recess exhibit, on either side of the opening, a rounded end 110, 111 serving as an abutment surface for the wire during rotation of the cutting head, which limits the risk of breakage at the eyelet, that is breakage of the wire at the opening 12.
The coil is accommodated in the recess on a central mandrel 13 comprising, on its outer surface 135′, a plurality of ribs 135″. The innermost turn of the coil being forcibly engaged onto the ribs 135″, the mandrel 13 and the coil are thereby in rotational engagement.
The mandrel 13 is positioned so as to turn selectively relative to the body 10. What is meant by selectively is that in normal operation of the cutting head, that is when it is driven in rotation by the motor of the cutting machine for the purpose of cutting vegetation, the mandrel 13 is fixed with respect to the body 10, and that it is caused to turn with respect to the body 10 only by an action from a user.
According to an embodiment, the mandrel 13 comprises a supporting plate 136 that extends radially from the peripheral surface 135 and that supports the coil 2. Because of the strain generated during use of the cutting head, the mandrel and the supporting plate are advantageously made of metal. Preferably, the supporting plate is not smooth but instead has a surface having a certain roughness that prevents the coil from sliding. For example, said surface may consist in an increased roughness of the supporting plate 136, or barbs regularly distributed on the surface. In an alternative or complementary way, the supporting plate may be pierced with a plurality of circular holes, distributed according to one or several concentric circles around the axis of rotation of the mandrel 13. Indeed, when the supporting plate 136 is being pierced, the metal that is pushed aside forms around each hole barbs that extend beyond the surface of the plate 136 and that exert a retaining function of the coil. The supporting plate 136 may thus be pierced with a first series of holes distributed along a first circle close to the mandrel 13, and a second series of holes distributed along a second circle close to the periphery of the plate 136.
According to an advantageous embodiment, the cutting head may further comprise a pressuring plate 35 arranged in the cover 30 against a spring (not shown), opposite to the supporting plate 136. Said pressuring plate 35 is intended to be in contact with the coil and, due to the force of the spring, exert a pressure onto the coil when it is in working position within the head. This allows maintaining the coil in a flat position between the supporting plate 136 and the pressuring plate 35, which in turn promotes a better rotational engagement of the coil and the mandrel.
According to an embodiment illustrated in
The connection between the two wires 20a, 20b, for example, is obtained by extrusion of a film 20c of the same material as the wires during manufacture of said ribbon. Said film 20c is thin enough to be torn for the purpose of separating the wires 20a, 20b over a certain length.
The ribbon is then being wound to form the turns, the turns 21 being temporarily bonded by the reciprocal retention arrangements.
In other words, the coil has two temporary connections: one between the two wires 20a, 20b over their length; the other between adjoining turns.
Then, the innermost turn of each wire is welded to the directly adjacent turn (and optionally shaped) as already described above.
FR 2 967 548
U.S. Pat. No. 4,024,635
WO 2014/020178
EP 0 435 795
Number | Date | Country | Kind |
---|---|---|---|
15305225.3 | Feb 2015 | EP | regional |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2016/053218 | 2/16/2016 | WO | 00 |