The present patent application for industrial invention relates to a process for making a seamless, reversible two-color garment. In particular, the garment can be a jersey, a pullover, a cardigan or any other type of knitwear, preferably made of valuable natural yarns, such as wool, cashmere and the like.
As it is known, a reversible (double-face) garment is a garment that can be worn inside out. Obviously, consumers mostly request reversible two-color garments, that is to say garments with different colors on the two sides of the garment.
Currently, reversible two-color knitted garments are made with linear knitting machines that use two yarns of different colors. Said yarns of different colors are knitted with a special technique, known as “vanish” knitting, wherein the yarn of a first color is disposed only on one external side of the garment and the yarn of the second color is disposed only on one internal side of the garment. The two-color garment that comes out of the knitting machine is a planar sheet that is then closed with seams in order to obtain the tubular shape that is typical of the body and of the sleeves of the garment. The hanging yarns of the garment coming out of the knitting machine are then looped in the seams.
Knitting machines have been recently introduced on the market, which are able to directly make a knitted garment with tubular shape, without any final seam used to close the garment with tubular shape.
Said knitting machines are known with the WHOLEGARMENT® trademark and are sold and marketed mainly by the Japanese company called SHIMA SEIKI. The wholegarment knitted technology allows for making a complete garment, directly in the machine, practically ready to wear with any looping operations and seams.
EP1672105 discloses a process for knitting a knitwear garment with sleeves using a wholegarment knitting machine without making seams.
However, wholegarment knitting machines are not capable of making “vanisè” fabric, that is to say with yarns of different colors respectively disposed on the internal side and on the external side of the garment. Therefore, the current wholegarment knitting machines can make a reversible knitwear garment, but cannot make a garment with different colors on the two sides.
U.S. Pat. No. 6,006,550 discloses a process for making a reversible knitted fabric having a first surface of a first color and a second surface of a second color.
DE10127740 discloses a process for making a two-color fabric; said process provides for obtaining a two-color effect by twisting different parts of fabric in such manner that these parts cannot be reached by any dye.
WO2005/028731 discloses a process for making a fabric comprising an internal side of a first color and an external side of a second color, which is different from the first one; said process provides for obtaining a two-color effect by spraying two different dyes on the internal side and on the external side of the fabric.
The purpose of the present invention is to eliminate the drawbacks of the prior art by disclosing a process for making a reversible two-color knitwear garment, which uses a wholegarment knitting machine, that is a knitting machine that delivers a finished garment, without the need to loop the fabric and make seams to obtain the finished product.
Another purpose is to provide such a process that is able to provide an aesthetically pleasant seamless garment.
These purposes are achieved by the present invention with the characteristics of the independent claim 1.
Advantageous embodiments will appear from the dependent claims.
In order to achieve the desired purpose, the applicant has revolutionized the traditional production, and has made numerous tests on a wholegarment knitting machine to improve the process for making a reversible two-color garment with wholegarment machines.
Additional features of the invention will appear clearer from the detailed description below, which refers to merely illustrative, not limiting embodiments, wherein:
With reference to the Figures, the process for making a reversible two-color garment according to the invention is disclosed.
A wholegarment knitting machine is used for knitting the jersey that forms the garment. Said machine is very sensitive to yarn count and even slightly different yarn counts can create considerable problems when knitting.
Therefore the first step of the process provides for searching for the ideal yarn. The yarn must be coarse, that is natural and not worked, and suitable for being dyed, that is a yarn of a neutral white or light grey color ready for dyeing, since the garment will be dyed successively.
Before purchasing a yarn, the yarn count is examined in order to make sure that the yarn count exactly respects the count used to set the wholegarment knitting machine. For illustrative purpose, a coarse wool yarn with Nm 2/30 yarn count is used.
A technology has been studied for setting the wholegarment knitting machine, which allows for obtaining a reversible two-color garment.
With reference to
The tubular body (2) has a bottom (4) and a neck (5). The sleeves (3) have cuffs (6).
The wholegarment knitting machine is set in such a way that the bottom (4) and the cuffs (6) of the knitted garment are closed and sealed during the knitting step. On the contrary, the neck (5) is left open.
For illustrative purposes,
Advantageously, the bottom (4), the cuffs (6) and the neck (5) are thicker with respect to the rest of the jersey. Such thickening of the bottom (4), of the cuffs (6) and of the neck (5) is obtained during knitting by re-twisting the primary wool yarn with a more elastic synthetic yarn, for example Lycra or other elastic fibers, in such manner to obtain thicker bottoms, cuffs and necks with respect to the rest of the jersey in order to ensure better wearability and longer life of the garment. However, if Lycra fibers are used to thicken the bottom (4), the cuffs (6) and the neck (5), it must be considered that Lycra does not absorb the color during dyeing. Therefore the Lycra yarn must be already colored with a very color that is similar to the final color of the garment to be obtained.
The wholegarment knitting machine is set in such a way to make a strip of fabric called track (7), on the sides of each sleeve (3) and on the sides of the body (2) of the jersey. Each track (7) is made by working with purl needles alternated with plain needles. In other words, the making of each track (7) provides that a working change is made on each sleeve (3) and on the sides of the body (2), alternating plain needles with purl needles. The function of the tracks (7) is to avoid problems in the following dyeing step. In fact, the color of the dye tends not to be absorbed correctly on the folded sides of each sleeve (3) and of the body (2) of the jersey, creating a non-uniform color in the jersey. Although they absorb a color that is slightly different with respect to the rest of the jersey, because of the different type of knitting, the tracks (7) look like a special decorative pattern.
The wholegarment knitting machine can also make eyelets and/or pockets. In fact, the successive making of pockets and eyelets with looping, as usual, would involve the application of seams that do not allow the garment to be reversible and seamless.
With reference to
The jerseys (1) coming out of the wholegarment machine have oil residues from the machine and stains. For this reason the jerseys (1) are checked and the stains are removed with trichloroethylene. Then they are dry-cleaned to eliminate the oil residues from the knitting machines.
After dry-cleaning, the jersey (1) is finished. The main difference between a standard finish and the finish obtained with the process of the invention is that:
Moreover, the separation yarns used by the wholegarment machine to seal the bottom (4) and the cuffs (6) of the jersey during knitting must be manually tied to prevent the risk of breaking the yarns during the dyeing step.
The only part of the jersey (1) that remains open after knitting is the neck (5).
With reference to
Advantageously, the patch (15) is made with the same yarn as the jersey (1) to prevent different yarns from absorbing the color in a different way during the dyeing step. This prevents the risk that the garment will have a different final color compared to the expected one.
The yarn used to tack the patch (15) must be very thin, in such manner that no colorless spots are left in correspondence of a tacking thread. For illustrative purposes, a 100% polyester GUTERMAN120 yarn is used.
After dry cleaning, finishing and tacking, the garment is pre-ironed. In fact, a pre-ironing step is necessary to obtain perfect dyeing.
The jersey (1) must be ironed on the tracks (7) made during the knitting step with the wholegarment machine.
The cuffs (6) and the bottom (4) of the jersey must be ironed in order to be enlarged and have the same width as the body (2) and the sleeves (3). In fact, the application, during the knitting step, of the thickening elastic fiber in the cuffs (6) and in the bottom (4) tends to make the cuffs (6) and the bottom (4) of the jersey tighter, with the risk of causing color accumulations in the cuffs (6) and in the bottom (4) during the dyeing step.
Such pre-ironing step also provides for press ironing to eliminate the creases formed on the jersey (1)
After the pre-ironing step, the jerseys are dyed with different dyeing cycles in a rotating dyeing tank.
Different types of dyeing can be used. For illustrative purposes, three examples of dyeing are mentioned below.
The sealed jersey is introduced in the dyeing tank and a first dyeing cycle is made using a washed-effect (frosted) dye. Considering that the jersey (1) is sealed, during said first dyeing cycle, a frosted dye coating is deposited only onto the external surface of the jersey.
Successively the jersey is extracted from the dyeing tank, the neck of the jersey is opened, removing the patch from the neck of the jersey and the jersey is turned inside out in such manner that the frosted dye is situated on the internal surface of the jersey. Now the inside out jersey is introduced again in the washing tank and a second dyeing cycle is made with a colored dye of type of color.
Considering that the frosted dye coating (contained on the internal surface of the jersey) absorbs less color than the external surface of the jersey, which is without frosted dye coating, during the second dyeing cycle, the colored dye will be absorbed more on the external surface of the jersey, which is without the frosted dye coating. Therefore a non-frosted (united) effect is obtained on the external surface of the jersey; on the contrary, a frosted effect is obtained on the internal surface of the jersey. In such a way, a two-color knitted garment is obtained.
In this example, instead of the frosted dye, a blue mist (indigo) dye is used, which has the same modes as the frosted dye, except in that the blue mist coating only absorbs the indigo dyes.
In the first dyeing cycle, the sealed jersey is dyed using a blue mist in such manner that a blue mist dye coating is obtained on the external surface of the jersey.
Then the jersey is extracted from the dyeing tank, the neck is opened and the jersey is turned inside out. The inside out jersey is introduced in the dyeing tank for a second dyeing cycle using a colored dye, for example a beige dye.
Consequently, a beige color is obtained on the external surface of the jersey, whereas the internal surface of the jersey has an indigo color because the blue mist coating only absorbs the indigo color, but not the beige color.
In order to obtain a pure two-color finish with two different colors, the tacking of the patch (15) is not carried out before dyeing, meaning that the neck (5) of the jersey is left open.
During a first dyeing step, the jersey (1), with the neck open, is dyed in a tank with a base color, for example orange. In this way a uniformly colored jersey with the base color both inside and outside is obtained.
Then the jersey colored with the base color is dried and the patch (15) is applied with tacking to close the neck and seal the jersey.
Therefore the jersey, which is colored with the base color and completely sealed, undergoes a second dyeing step in a tank with a frosted dye, that is a dye that does not absorb other colors. For example, a frosted blue dye can be used in combination with the base orange color to give a brown color. As a result, a brown frosted dye coating is created on the external surface of the jersey.
Likewise in the previous cases, the jersey is extracted from the tank, the neck is opened and the jersey is turned inside out in such manner that the frosted dye coating is situated inside the jersey. Then a third dyeing cycle is made with a colored dye, for example of gray color. As a result, a gray color is obtained on the external surface of the jersey. On the contrary, the brown color remains on the internal surface of the jersey with the frosted dye coating that does not absorb the gray color.
In this way a pure two-color (gray and brown) is obtained respectively on the two sides of the jersey.
At the end of the dyeing step, the patch (15), which was applied during tacking, and the seals of the bottom and of the cuffs, which were applied during knitting, are removed.
The dyeing process, wherein the jerseys are rotated in a drum inside a dyeing tank, can pull threads or make holes. Therefore quality control is necessary to check the integrity of the garments, cut the threads ad mend the holes by recreating the warps by hand.
Being a reversible garment, brand labels or composition/washing labels cannot be applied, like in a non-reversible garment. For such a purpose, as shown in
Then the brand label (20) is applied with four hand stitches (21), on the inside of the cuff (6) of the sleeve of the jersey. In such a way a pocket (22) is created between the cuff (6) and the brand label (20). The composition/washing label (23) is concealed in the pocket (22) between the cuff (6) and the brand label (20). In order to see the composition/washing label (23), the user can pull out the composition/washing label (23) from the pocket (22), as shown in
Numerous variations and modifications can be made to the present embodiments of the invention, which are within the reach of an expert of the field, falling in any case within the scope of the invention as disclosed by the attached claims.
Number | Date | Country | Kind |
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102015000089256 | Dec 2015 | IT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2016/082396 | 12/22/2016 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2017/114751 | 7/6/2017 | WO | A |
Number | Name | Date | Kind |
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20100095709 | Ando | Apr 2010 | A1 |
Number | Date | Country | |
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20200308748 A1 | Oct 2020 | US |