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1. Field of Invention
This invention pertains to a method of producing a printed fabric and more particularly, a process in which one side of the fabric is first coated with dyestuff and then a coating is applied in a decorative pattern or motif that affects the manner in which the dyestuff adheres to the fabric so that when the fabric is washed, some of the dyestuff is removed from the fabric.
2. Background of the Invention
There are many ways of producing decorative woven fabrics for clothing, furnishings and other uses. One popular way is to print patterns on fabrics. The most common fabric printing methods include silk screening and rotary printing. In many instances these methods are useful to produce printed fabrics with many different types of designs that have a high quality and are attractive esthetically.
However, these methods are not very effective in producing fabrics with very fine details. For example, designers and customers would like to have printed fabrics that have a knitted or so-called ‘Jacquard’ look. Neither the screening methods nor standard rotary printing methods are capable of producing fabric with patterns having sufficiently fine details to achieve this look.
Conventionally, a printed fabric is made by bleaching a raw fabric and applying dyestuff to one surface, using a silk screening, a rotating print roller, etc. The fabric is then heated to set the dyestuff, washed and then inspected.
In order to make a fabric with motifs that have finer details, in the present invention, the conventional dyestuff is used to coat one side of a fabric so that the side has a ground or base color. Next, coating is applied. The fabric is then padded and heated. The fabric is then washed. During washing, dyestuff in the areas of the fabric covered by the coating is removed leaving a visible pattern on the fabric that has a lighter shade then the ground color.
Preferably, the dyestuff and the coating are applied using a rotary print roller.
The amount of dyestuff removed from the fabric during washing is dependent on the concentration of an active ingredient in the coating. A bigger concentration of this active ingredient (for example PEG) results in more dyestuff being washed off leaving the motif with a lighter shade.
The resulting fabric has a motif that is more precise and has finer details then fabrics made with the prior art methods. More specifically, the coating and the resulting motif can be selected to provide the fabric with a unique and intricate pattern that gives the fabric a knitted or Jacquard look.
Referring first to
Next, in step 16, the dyestuff is printed in a preselected pattern on the bleached fabric using either a silk screening technique or a rotary printer.
In step 18 the fabric is heated (and, optionally, pressed) to cause the dyestuff to adhere to the fabric fibers and to insure that the fabric is colorfast.
In step 20, the fabric is washed to remove excess dyestuff and other matter. Finally, the fabric is tentered to set its physical dimensions (step 22) and then inspected (step 24).
As discussed above, a problem with this process is that it cannot be used to make a fabric with a print having fine details. For example, the process cannot be used to make a fabric having a print imitating the look of a knit material (the so-called Jacquard look).
The present invention is now described in conjunction with
In step 16 the dyestuff is applied to one side of the bleached fabric 100, preferably using a conventional rotary printing roller (not shown). The result is a base- or ground-color fabric 102 shown in
Next, in step 17A a coating is applied to the base-color fabric, again preferably using a printing roller. However, the printing roller is provided with a pattern defining on the fabric a selected motif. A printing machine with a roller suitable for this purpose is the DR-9000 printing machine made by the Daiyang Machinery Company of the Republic of Korea.
Thus, the fabric 104 from step 17A includes two different types of regions: region 104A with the base-color formed by the dyestuff, and regions 104B formed by the coating. It should be understood that in
The coating forming regions 104B may be composed of various materials and compositions. One preferred composition includes an aqueous PEG (polyethylene glycol) solution (available from Sanyo Chemical of Japan, Shell of the United States, etc.). A typical solution may consist of the following ingredients:
PEG-400 is an aqueous solution of PEG. The concentration of PEG in the PEG-400 aqueous solution may vary in accordance with the effects that are desired, as discussed below.
Importantly, the coating applied during step 17A is not visible on the fabric and regions 104B are shown in
Once the coating is applied, in step 17B a padding step is performed during which the fabric is padded and pressed using a pressure nip or other means to insure that the dyestuff and the coating stay on the fabric. Next, in step 17C, the fabric is aged for about 40-50 minutes.
After aging, the standard process is resumed. In step 18 the fabric is heated to set the dyestuff. In step 20 the fabric is washed.
In the conventional process, the dyestuff is deposited on the fabric uniformly, and excess dyestuff is removed uniformly as well, during washing. Therefore, after printing, the appearance of the fabric remains unchanged. However, in the present invention, the presence of the coating changes the characteristics of the dyestuff and/or the fabric fibers. As a result, during washing a substantial amount of the dyestuff is removed from the regions 104B and therefore these regions are about 10-20% lighter than the regions 104A. In this manner, the pattern or motif defined by the coating during the printing step 17A becomes clearly visible, as shown in
After washing, the fabric 106 is tentered in step 22 and then inspected in step 24.
The resulting fabric has a pattern or motif that can have much finer details than the fabric obtained from conventional printing processes. Moreover, as discussed above, the difference in the shading between the ground color and the motif is easily but precisely controlled by changing the composition of the coating.
While the invention has been described with reference to several particular embodiments, it is to be understood that these embodiments are merely illustrative of the principles of the invention. For example, instead other coating compositions may be used, such as a sodium formaldehyde foxilate rongalite-c available from Hunan ZhongCheng Chemicals Co. Ltd. of Hunan, China. In addition, the sequence of the steps can be changed. For example, the coating could be applied before the printing of the base color. Alternatively, the coating step may be repeated with different solutions, thereby generating fabrics with multiple shadings. Accordingly, the embodiments described in particular should be considered as exemplary, not limiting, with respect to the following claims.
While the invention has been described with reference to several particular embodiments, it is to be understood that these embodiments are merely illustrative of the principles of the invention. Accordingly, the embodiments described in particular should be considered as exemplary, not limiting, with respect to the following claims.