The present invention relates to a hook for a tufting machine.
In a tufting machine, a needle carrying a yarn reciprocates through a backing material in order to form a loop of yarn. The loop of yarn is caught on the hook to retain the loop as the needle is retracted.
The hook has a working portion which is the part that receives the loops of yarn and a shank portion via which the hook is connected to an underlying structure such as a bar or block via which it is connected to the tufting machine. The lower edge of the working portion is provided with a cutting edge which cooperates with a knife to cut the loops of yarn in order to form a cut pile carpet.
A typical hook used in a tufting machine is illustrated in
The needle 1 is shown above backing material 2 having formed a loop of yarn 3 around the working portion 4 of a hook 5. The cutting edge 6 is provided in the lower left hand corner of working portion 4 and cooperates with a knife 7 which will cut the loop of yarn 3 formed on the hook 5. As is apparent from
The J-Cut effect is further reduced by making the working portion 4 of the hook as thin as possible as, in general, the aim in a tufting machine is to form a carpet with a pile which is as uniform as possible. As an exception to this general rule, some tufting machines have been designed to specifically exaggerate the J-Cut effect. This may be done, for example, for a tufting machine which can produce artificial grass. In order to provide a more realistic look, it is desirable to have an uneven pile size on artificial grass. As well as being desirable from a realistic point of view, this can produce increased technical performance as the feeling of the grass under foot and the interaction with a ball again mimics the effect of natural grass.
One example of such a machine is disclosed in U.S. Pat. No. 3,152,563. This discloses a hook having an insert which is inserted into the working portion of the hook on the opposite side to the cutting edge. The insert extends below the cutting edge thereby creating a longer path for the yarn which extends around the insert as compared to the path with extends to the cutting edge. Since the insert may not extend below the bill of the hook, to guarantee that the yarn loops will remain on the hook, however, its vertical dimensions are limited. Increasing the height of the hook, resulting in a lower bill in vertical direction and hence more space for the insert, is greatly limited by limitations imposed by the pick-up process of the yarn loops by the conventional tufting needles. Consequently to be able to produce more pronounced J-cuts the thickness of the hook is increased. As a result of this, the standard means of fastening a hook with slotted bars and screws or moulding it in a module block cannot be used. Further, the thicker shank means that less supporting material is available to secure the hook thereby leading to a weakened connection.
A second example is disclosed in GB931360. This is similar to U.S. Pat. No. 3,152,563 in that it discloses a downwardly extending insert which can create a longer path on the opposite side from the cutting edge to provide an enhanced J-Cut. In this case, however, the insert is pivotally mounted so that it can be moved vertically to a retracted position level with or above the cutting edge in which it does not create the enhanced J-Cut. The vertical dimensions of this insert are also limited. To provide a more pronounced J-cut the thickness of the hook is increased.
Moreover, the yarn tension defines the position of the insert. If the amount of yarn fed is below a certain threshold, the yarn tension is high enough to position the insert above the cutting edge and no J-cut is created. If the amount of yarn fed is above this threshold, the yarn tension will decrease, the insert will move a retracted position resulting in an enhanced J-cut. With this insert, the possibility of varying the pile height of the tufts is greatly reduced, as the pile feed also determines whether a J-cut is produced or not.
According to a first aspect the present invention, there is provided a hook according to claim 1.
The approach taken by the present invention is the opposite of a conventional tufting approach in that it deliberately provides a working portion which is thicker than the shank portion. This will exaggerate the J-Cut effect in that the length between the two yarns cut from a loop is increased because of the additional yarn path around the thicker working portion of hook. At the same time, the thinner shank portion allows a conventional hook mounting mechanism to be used. As far as we are aware, a hook for a tufting machine where the shank portion has a smaller thickness than the working portion is unique in a tufting machine.
A hook of this type is particularly designed for a tufting machine which can produce artificial grass.
The maximum thickness of the working portion in the region above the cutting edge is preferably at least 1.2 times, more preferably at least 1.5 times and most preferably at least 2 times greater than the thickness of the shank portion. On the other hand, the maximum thickness of the working portion in the region above the cutting edge is preferably less than 4 times the thickness of the shank portion.
In a cross section in a plane perpendicular to the cutting edge, the ratio of the maximum width of the hook to the maximum height is at least 0.3, preferably at least 0.4, more preferably at least 0.5 and most preferably at least 0.6. On the other hand, this ratio is preferably less than 1.2.
These ranges provide an appreciable thickness in the working portion of the hook which provides an enhanced J-Cut effect. On the other hand, the dimensions provide a hook which can readily be manufactured and accommodated within the existing tufting machine framework without requiring significant modifications.
Whilst it is possible for the working portion of a hook to be provided with a chamfer on the side of the hook opposite to the cutting edge, this is counterproductive in producing a J-Cut effect as it counteracts the increased thickness of the working portion. Therefore, preferably, the hook is devoid of a chamfer on the side of the hook opposite to the cutting edge.
Preferably the working portion of the hook tapers towards the tip of hook, resulting in a tip of conventional thickness and a smooth pick-up of the yarn loops on a tufting machine with conventional tufting needles.
The hook may be formed of a single piece of material. In this case, the material used is thicker than the material used for a conventional hook and the hook is cut to the desired dimensions.
Alternatively, the J-Cut portion may be formed by an insert extending from a main body of the hook to provide the greater thickness. Preferably the insert also forms the cutting edge of the hook. When incorporating an insert which also forms the cutting edge, the insert can be made of a harder material which increases the performance of the hook.
The insert is preferably rigidly attached to the main body of the hook. However, the insert may alternatively be movable with respect to the main body of the hook to vary the size of the J-Cut forming portion.
This forms a second aspect of the invention, according to which there is provided a hook according to claim 16.
Examples of hooks in accordance with the present invention will now be described with reference to the accompanying drawings in which:
Before describing the specifics of the present invention, the general operation of a hook in a tufting machine will be described with reference to
A tufting machine is provided with a row of needles 1 extending across the width of the machine. Only one of these is shown in
Each hook has a working portion 4 which is the part of the hook which includes the cutting edge 6 and a shank portion 12 via which the hook 5 is connected to the tufting machine. In this case, the shank portion 12 can have a conventional thickness and hence can be connected to a bar or block 13 via bolts 14 in a conventional fashion. Similarly, the knives 7 are mounted to a knife bar 15 such that a number of knives are reciprocated together.
The first example of the present invention is shown in
In most senses, the hook is conventional. In particular, in the side view of
As is apparent from
In order to create the hook with the thicker working portion, conventional techniques can be used in terms of cutting, treating and grinding the hook. The only difference will be that the starting material required to make the hook will be thicker.
The second example of the hook is shown in
In this case, rather than starting from an entire hook which is thicker and then removing the extra material in the shank area 12, the hook is made as a hook of a conventional or common thickness as best appreciated from
As is apparent from
The third example is shown in
As can be seen in
Number | Date | Country | Kind |
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1816207.3 | Oct 2018 | GB | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2019/076898 | 10/4/2019 | WO | 00 |