GB2089856A - Felting needle - Google Patents

Abstract

An improved felting needle is provided having a conical tip (15) formed on opposite sides with flats (25) which give the needle tip a wedge-shaped configuration. The leading edge of the needle is rectilinear and preferably in two symmetrical rectilinear sections (27, 28) providing between them an included re-entrant angle in the range 120-180 DEG . Other embodiments show outwardly inclined leading edges (17, 18), and a single continuous leading edge which may be normal or inclined to the needle axis, see figs. 7, 9 respectively. <IMAGE>

Description

SPECIFICATION Felting needle This invention relates to felting needles.

In the past, felting needles have been grouped in two general types. The first type is the regular felting needle with a round, pointed end and barbs spaced at various points along the lateral edge of the blade. Such a needle is designed to interlock fibers so as to produce a felted fabric. The second type of needle is the forked needle which has two spaced-apart points and a fiber raceiving slot between them for pushing fibers toward a batt.

The primary function of such a needle is to embellish the surface of felted fabrics.

Patents which illustrate needles in the first group are my own U.S. Patents: 3,307,238; 3,641,636; 3,815,186; 3,844,004; and 4,156,305; and patents which illustrate needles in the second group are my own U.S. Patents 3,727,276 and 4,110,875. The older, longestablished felting needle with barbs formed in longitudinal lateral edges of the needle body have long been known and specific terminology has become identified with such needles, such as barb angle, throat depth, kickup and throat length. Such portions of a felting needle must be held to very close tolerances to make possible the production of the desired fabric. Barb angles, with their precise forward inclination, are very critical. It is essential on the regular felting needle that the barb angle be such that engaged fibers can shed off the barb tip and be felted into the fabric.The design of the forked needle with longitudinal sidewalls adjacent the fiber-receiving slot makes shedding impossible and confines the function of the needle to the production of fiber loops and tufts.

In the present invention in order to overcome the disadvantages of the felting needles or the tufting needles of the prior art, I provide a unique barb structure at the forward tip of the needle.

This I have identified as an "open double-barb".

In one embodiment, the needle has a spatulate or wedge-shape tip, with a barb which has two forwardly-inclined barb angles diametrically opposed to each other across the centerline of the needle. The two symmetrical barb angles cooperate to provide a single fiber-engaging indentation at the leading edge of the needle.

Contrary to the ordinary barb formed in the lateral edge of a needle body, this symmetrical open double-barb with its "positive" but very slight barb angle allows the fibers to slip off to either side of the needle when the indentation is "loaded" with fibers. This clearly distinguishes from the standard barb heretofore known in the art wherein the barb with its lateral throat in the needle body prevents the fibers from slipping off with resultant damages to the fibers.

In another embodiment the barb angle can be zero degrees (i.e., at 900 to the centerline of the needle), and in a third embodiment a "negative" barb angle is provided, each of which afford even greater ability to shed the fibers and prevent fiber damage.

Because the open double-barb is formed on the tip of the needle, it always accepts fibers and thus the needle always "loads". The loading can be controlled by the barb angle. Also, because of its location, the open double-barb only needs to penetrate the bed plate and thus considerable needle breakage is eliminated. A further attraction of this needle is that because of its construction, the length of the needle stroke is shortened.

Another advantage of the double barb is that it can consistently pick up extremely small punching loads, and since small punching loads are the only way to eliminate needle marks and craters in the fabric, the open double-barb needle of the present invention produces a much finer and more attractive fabric.

In addition, because the needle does not enter the bed plate, the full capacity of the needle loom is utilized, and this means that a higher number of strokes per minute and thus higher density needle board providing higher fabric production is available.

The invention will be further described with reference to the accompanying drawings which illustrate various preferred embodiments.

In the drawings wherein like reference characters indicate like parts: FIGURE 1 is a side elevational view of a felting needle having the open double-barb of the present invention.

FIGURE 2 is a greatly enlarged fragmentary front elevational view of the tip of the felting needle, showing the details of the open doublebarb.

FIGURE 3 is a side elevational view of the tip of the needle of FIGURE 2.

FIGURE 4 is an end elevational view'taken generally along line 4-4 of FIGURE 2.

FIGURE 5 is a schematic diagram of the tool used to form the flat wedge-shaped portion of the tip of the open double barb of the present invention.

FIGURE 6 is a fragmentary front elevational schematic view of the needle tip of FIGURE 2, illustrating "positive" barb angles.

FIGURE 7 is a view similar to FIGURE 6, illustrating zero barb angles.

FIGURE 8 is a view similar to FIGURES 6 and 7 illustrating barb angles.

FIGURE 9 is a view similar to FIGURES 6 and 7 illustrating a further embodiment in accordance with this invention and in which the needle tip is asymmetric.

Felting needles, like the felting needle 10 of the present invention, generally include a shank 11, a crank 12, and a blade 1 3. The blade 13 may be circular in cross-section with its end tapered to a tip 14. It is at this tip 14 that the open double-barb of the present invention is formed.

For the purpose of illustrating this invention, the drawings must be greatly enlarged, and it is to be understood that felting needles of which this invention is illustrative, are made of relatively fine wire. For instance, the felting needle of the present invention may be a 32 gauge needle, which is approximately .026" in diameter. The blade 1 3 shown in the drawings of FIGURE 1 appears much larger than .026" in diameter, and FIGURES 2 and 3 are shown on a scale of approximately 1/4" to .001".

The end of the blade 13, where it tapers to the tip 14, is ground in the shape of a cylindrical cone at 1 5. The included angle of this portion 1 5 is 120, as is shown particulariy in FIGURES 2 and 3, and the point of the tip preferably is .006" in diameter.

This dimension is shown in dotted lines in FIGURE 3.

Thereafter, I form a wedge-shaped portion in the tip of the needle by use of a swaging tool illustrated schematically in FIGURE 5. This tool may include a lower stationary portion 1 9 and an upper movable portion 20, which come together at the meeting line 21. Each of the portions 1 9 and 20 has an angular surface 22 and 23, respectively, ground therein at an angle of 150 to provide an included angle between the two tool portions of 300.

Then the tip of the needle is piaced between the swaging tool portions 1 9 and 20, whereupon the tools are brought together to flatten the needle tip between the surfaces 22 and 23, to form a spatulate wedge-shaped portion, defined by the surfaces 24 and 25 as shown in FIGURES 3 and 4.

During formation of the wedge-shaped portion, the outermost end of the tip is not only flattened (to provide the surfaces 24 and 25), but it also may expand slightly sidewardly beyond the .006" dimension, as is illustrated in FIGURE 2.

Thereafter, in one embodiment illustrated in FIGURE 2, 1 form a 1400 included angle in the wedge edge 26. This can be done either by swaging or by grinding, but it will be clearly noted from the illustrations in FIGURE 2, and particularly in FIGURE 3, there are no sharp corners and the wedge-edge is a smoothly rounded surface.

The open double-barb illustrated in FIGURES 2 and 6 includes one surface 27 and another surface 28. The throat length of approximately .006" is shown between the arrows 29 and 30 in FIGURE 2.

The throat depth of approximately .0015" is indicated between the arrows 31 and 32.

Thus I have provided a felting needle with a body portion having a wedge edge front end. In one embodiment, that wedge edge is the forwardly directly fiber-engaging open doublebarb located equally on each side of the centerline of the needle. It consists of opposed symmetrical outwardly and forwardly extending surfaces which engage the fibers to be felted. The indentation may be curved or generally concave, or it may be angular, and I have chosen to illustrate an angle between the fiber-engaging surfaces of 1400. This design is specifically intended to felt the fibers uniformly on both sides of the needle.

In the embodiment illustrated in FIGURE 6, the indentation formed by the surfaces 27 and 28 provides positive barb angles which may vary from O to 300, and I have illustrated a 200 angle.

In the embodiment illustrated in FIGURE 7, the barb angles are 00, that is, the leading edges of the open double barb are in alignment and disposed at a 900 angle to the centerline of the needle, as is illustrated at 16 in FIGURE 7.

In FIGURE 8, 1 illustrate still another embodiment wherein negative barb angles are chosen and surfaces 17 and 18 can be disposed at a negative angle of between 0 to 300. In FIGURE 8 I have illustrated a negative angle of 100.

With the conventional throated-barb felting needle, the fabric can be entangled and compacted just so far and a point is reached where further needling becomes counterproductive. At this point the barb engages and holds fibers already entangled into the fabric, there is no give, and the continuing downward needle action breaks the engaged fibers. With the provision of a felting needle such as shown in FIGURES 7 and 8, there is no throat or pocket that holds fibers. These needles provide a front end fiber engaging surface having the configuration and needle action of a sliding cam which imparts a transient friction motion to work the fibers into the fabric and thus increase its density without fiber or fabric damage.

It is clear that this open double-barb configuration does not include any kickup.

Because the double-barb is on the wedge-edge of the needle, and open to accept fibers, it always "loads". Furthermore, because of its location, the open double barb need penetrate only through the batt of fibers, and it does not enter the bed plate.

Thus considerable needle breakage is eliminated.

The open double-barb wedge edge needle of this invention thus eliminates needle marks and craters in the fabric and permits more rapid operation of the felting machine, and along with this high density performance, improved operation, better productivity and a better quality of finished product is insured.

Claims (16)

1. A felting needle comprising a round-ended conical tip provided on opposite sides with tapering flats providing said tip with a wedgeshape configuration and rectilinear leading edge.

2. A needle according to claim 1 , wherein said leading edge is formed as a single continuous line.

3. A needle according to claim 2, wherein said leading edge is normal to the longitudinal axis of the needle.

4. A needle according to claim 2, wherein said leading edge is inclined to the longitudinal axis of the needle.

5. A needle according to claim 1, wherein said leading edge is formed as two mutually inclined rectilinear sections.

6. A needle according to claim 5, wherein said mutually inclined rectilinear sections meet on the centre line of the needle.

7. A needle according to claim 6, wherein said mutually inclined rectilinear sections are symmetrical.

8. A needle according to claim 7, wherein said mutually inclined surfaces form an included reentrant angle in the range 120 to 1 800.

9. A needle according to claim 8, wherein said included re-entrant angle is 1400.

10. A needle according to any one of claims 5-7, wherein said rectilinear sections are inclined at positive angle of up to 300 to the normal to the longitudinal axis of the needle.

11. A needle according to claim 10, wherein said angle is 200.

12. A needle according to any one of claims 5-7, wherein said rectilinear sections are inclined at a negative angle of up to 300 to the normal to the longitudinal axis of the needle.

13. A needle according to claim 12, wherein said angle is 100.

14. A needle according to any one of the preceding claims, wherein said conical tip is of a circular cross-section and has a cone angle in the range 7--150.

15. A needle according to claim 14, wherein said angle is 120.

16. A needle according to any one of the preceding claims, wherein said flats taper at an included angle of 30".

1 7. A needle according to claim 1, substantially as hereinbefore described with reference to the accompanying drawings.