Patent Grant
11535980
The disclosure generally relates to a plant for the continuous dyeing of warp chains for fabrics and, in particular, to a process and a multifunction dyeing apparatus with indigo and/or other dyes to which yarn chains for the warp of denim fabrics are continuously subjected. More in particular, the present disclosure relates to a process and a multifunctional continuous dyeing apparatus that work with reduction baths.
A typical application of such apparatus is that of the continuous dyeing of warp chains for denim fabrics with indigo or other dyes. Denim is the fabric used for making jeans and “sportswear” articles in general, and is quantitatively the most used fabric in the world.
The success of the denim-blue jeans union is due precisely to the dyeing of the warp of this fabric with indigo. Indigo is one of the oldest dyes, not easily applied to cotton for which it has poor affinity, but which has a unique feature that makes the fabric, and as a result the garment, have a shiny and pleasant appearance over time. Blue jeans are in fact appreciated for their typical Navy tone that gradually, because of repeated washings, takes on a lighter tone until it reaches a bright blue. As far as we know, no other dye has similar properties. Other classes of dyes, after many washes, turn towards dirty grey, or stain the white yarn with an unpleasant blue/grey color. The above peculiarity, together with that look of vintage garment, which is evident with the abrasion in exposed areas and that creates a plastic effect on the wearer's body, are the charm of blue jeans, which manufactured and treated in many ways are and will remain the world's top-selling garment.
One of the features of indigo dye, which makes it unique, is the particular dyeing method required for its application to the cotton yarn. This dyeing method has remained virtually unchanged since the time of vegetable dye to the present day, in over one hundred years since its synthesis.
The indigo dye, due to the relatively small molecule and low affinity with cellulose fiber, in order to be applied must not only be reduced in alkaline solution (leuco), but it also requires being subjected to a plurality of impregnations alternated with squeezing and subsequent air oxidation. In practice, a medium or dark color tone is obtained only by subjecting the yarn to a first dyeing (impregnation, squeezing, oxidation) immediately followed by multiple over-dyeing, the more numerous the darker the tones and the higher the required color fastness.
This particular dyeing method, typical of the indigo dye, dramatically highlights the importance of compliance with certain basic parameters related to the immersion and oxidation times. This is to allow the dye to impregnate and evenly distribute in the cortical or surface layer of the yarn (ring dyeing) and, after a perfect squeezing, to oxidize completely before entering the next tank, so as to “remount”, i.e. intensify the color tone.
Unfortunately, in addition to these parameters, continuous dyeing with indigo is also influenced by many other factors relating to the different physical-chemical contexts of each individual plant, and the environmental conditions where the plant itself is installed, such as temperature and relative humidity of the air, upwind condition, altitude, etc. In addition, the different dyeing conditions (such as number of tanks, their capacity, pick up, circulation rate and type of the dye bath, type and accuracy of the automatic indigo, caustic soda and sodium hydrosulphite dosing systems, etc.) and the different conditions of the dye bath (such as temperature, concentration, pH, Redox potential, etc.) not only have a decisive impact on the dyeing results (such as greater or smaller dyeing intensity, color fastness, corticality, etc.), but also contribute considerably to determine the final appearance of the garments after the various washing and finishing treatments to which they are normally subjected. It should also be noted that, in contrast to other groups of dyes for which affinity for cotton increases with increasing temperature, the color affinity and depth with indigo, the latter due to greater dye corticality, increase with decreasing temperature.
The most important and qualifying operation of the entire production cycle of denim tissue is that of continuous dyeing, with indigo dye and/or with other dyes, of the warp yarn chains before they are put on the loom to produce the fabric. Classic denim is in fact manufactured by weaving pre-dyed cotton threads. In particular, only the warp is dyed, while the weft is used raw.
The continuous dyeing of warp chains for denim fabrics is mainly carried out according to two systems, namely the so-called “rope” system and the so-called “flat” or “wide” system. The two systems above, despite differing substantially, however, in the case of dyeing with indigo share the use of the same dyeing method, consisting essentially of three operational steps that are repeated several times: yarn impregnation with the reduced dye, squeezing to remove the excess dye bath and dye oxidation by exposure of the dyed yarn to air.
Typically and traditionally, dyeing the warp chains for denim fabrics with indigo is carried out, both in the rope system and in the wide system, in open and low temperature tanks. In detail, in the two systems, the continuous dyeing plants with indigo typically consist of 3-4 pretreatment tanks, 8-10 dyeing tanks and 3-4 final washing tanks. All tanks are provided with a squeezing group to remove the excess dye bath, while the dyeing tanks are also provided with groups of rollers exposed to air for the oxidation of the yarn.
The dyeing tanks are of the open type, each of which has a dye bath capacity ranging from 1000 to 4000 liters, containing about 4-11 meters of yarn. These amounts of dye bath determine the total volume of the bath circulating in the plant, which then can range from about 10,000 to 40,000 liters. The dye bath contained in each tank is recycled continuously to ensure homogeneity of concentration in each tank. This circulation is normally carried out by various known piping systems, with high capacity and low pressure centrifugal pumps to prevent harmful turbulence. The movement of the dyeing bath results in the continuous renewal of the superficial part of the bath itself, which is in contact with the air, the tanks being open at the top, and then it causes the oxidation thereof. The dye bath oxidation results in the continuous depletion of the reducing agents contained therein, i.e. sodium hydrosulphite and caustic soda, and this to a greater extent the higher the temperature of the dye bath.
However, the several oxidation steps concur, to a greater extent than mentioned above, to deplete the dye bath of the same elements (sodium hydrosulphite and caustic soda) which impregnate the yarn are multiple. These oxidation steps are an integral part of the dyeing cycle and basically consist of an exposure to air, between one tank and the other of the 6-10 dyeing tanks of the plant, of about 30-40 meters of yarn impregnated with leuco. The yarn is therefore overall exposed to air for several hundred meters throughout the dyeing plant.
Based on the foregoing, it is necessary to continuously replenish the dye bath with the amounts of caustic soda and sodium hydrosulphite destroyed by the above oxidation, so that such a dye bath is constantly maintained in optimal chemical conditions for the best dyeing yield and to ensure consistent and reproducible results. These continuous additions to the dye bath constitute a considerable economic cost, increase the salinity of the dye bath itself, with consequent dyeing problems, and also create a remarkable final washing water pollution.
Of course, the dye bath must also be continually and constantly admixed with dye, in condition of concentrated leuco, in the amount necessary to obtain the desired color tone. For the automatic continuous dosing of the indigo dye, caustic soda and sodium hydrosulphite, various systems may be used such as dosing pumps, weighing, volumetric, mass systems, etc., however all known as normally used also in other textile processes.
Of course, the higher the volume of the dye bath, the more time is required to bring a new dye bath to the chemical/dyeing balance needed to constantly obtain the same color tone. Equally long will be the response time to any corrective actions, and this does not help the achievement of quality.
Another peculiarity of the indigo dye is due to the fact that dye baths with this dye are never substituted, if not to change the color tone. As mentioned above, indigo dye baths are instead continually reused by adding sodium hydrosulphite, caustic soda and dye in order to maintain constant the chemical/dyeing balance thereof. Each dyeing plant then has a certain number, equal to the number of variants of blue in production, of containers with a total capacity of all the dyeing tanks. These containers are used for storage and reuse of the dye baths.
For quality purposes, it is of the utmost importance to be able to keep the physical and chemical conditions of the dye bath constant for all the time needed to dye the entire batch of yarn. The average time is between 15 hours and 30 hours depending on the yarn chain length and the dyeing rate. Unfortunately, despite ongoing mechanical and hydraulic improvements of the dyeing plants and the use of sophisticated control and dosing systems, for the large volumes involved, as well as for the many reasons outlined above, which individually or in combination can contribute to creating undesired variations of the conditions of the dye bath, continuous dyeing with indigo remains a complex operation.
Besides the foregoing, in the flat dyeing system the length of yarn threaded into the dyeing/sizing line, which can reach 500-600 meters, makes it difficult to control the plant. In the flat system there is also an economic drawback due to the amount of yarn that is lost at each batch change. In this operating condition, in fact, all the amount of yarn mentioned above, which forms the tail of the yarn batch, whose dyeing has ended and that remains in the plant after its stoppage, must be considered as lost, as it is not evenly dyed. Likewise, also the same amount of yarn which forms the beginning of a new batch and which, connected to the tail yarn, replaces it in passing the dyeing plant (made at low speed for safety and technical requirements) is not evenly dyed and must therefore be discarded.
In addition, further complicating the production of denim fabric was the addition of various economic and ecological problems, also aggravated by the fact that the production of this fabric is extremely diversified and is carried out in batches of shorter lengths. This factor is the result of the fact that, compared to what happened in the past, denim fabric is increasingly used in the fashion industry, where not only a significant operational flexibility and timeliness of production are required, but there are also constant requests for new original and exclusive articles to stimulate sales, to win the competition and gain new markets.
In fact, over time, denim fabric has undergone a remarkable and constant evolution, moving from an initial production with warp dyed with indigo only up to the addition of several manufacturing operations, such as caustic soda pre-treatment, pre-dyeing, over-dyeing, etc., which entailed the completion of the dyeing plants with respective aggregated devices. Important changes have occurred also in the yarns employed, from cotton alone to various mixtures of fibers, from the open end cotton to the so-called ring spun cotton, from large to fine textile measures, as well as elastic fibers and an increasingly higher thread count to get increasingly lighter denim.
It is in the finishing operations that in order to follow fashion, there has been a technological revolution that has seen the denim fabric evolve from being used as it was produced on the loom. Washing, mercerizing, over-dyeing by immersion, foaming or coating operations were in fact added, using the latter two systems also for the application of special products in order to vary the appearance of the fabric, especially to achieve particular effects after washing of the garments.
The influence of fashion is even more evident in the jeans industry, where a new productive activity consisting of denim laundries has been created. Once, as described above, the gradual fading of the jeans, an effect that gives a particular tone of bright blue and a pleasant impression of vintage garment, was the natural result of personal use and the resulting multiple washings. These effects, as well as many others, are today already present on new garments and are precisely added by denim laundries that, with a multiplicity of possible pre-treatments, allow the end users to enjoy them immediately. The jeans in laundries are washed, bleached with a variety of chemicals, enzymes, ozone and/or laser, treated with pumice stone, sanded, etc. These treatments give the jeans a vintage look, which goes even to create rips in the fabric.
All these final treatments, whether performed directly on the denim fabric or those performed on the garments, necessarily require that the characteristics of the basic dye, i.e. that of the warp dye, are suitable and concur with them to obtain and highlight the desired effects. It should be noted that many of these treatments, due to the increasing ecological awareness, are now made with less aggressive and less polluting products and consequently underwent a lengthening of the working times. Hence there is the need for the dyeing of the warps to be very intense in color but also very cortical or superficial, so as to reduce the times of these expensive treatments while still providing a good final contrast.
From a dyeing point of view, part of the current requests coming from the fashion industry are possible also on traditional dyeing plants, perhaps using some particular tricks. Other requests coming from the fashion industry are solved only with dyeing plants that use the new dyeing technology in inert atmosphere (under nitrogen) described in patent EP 0799924 B1 and better in patents EP 1771617 B1 and EP 1971713 B1 on behalf of the same Applicant. This new and original working condition, in inert environment, allows eliminating many problems of the traditional indigo dyeing system, with respect to which it has not only the advantage of reducing the number of dyeing tanks, but dramatically reduces also the consumption of caustic soda and sodium hydrosulphite. Moreover, with a better fixation of the dye to the yarn, a substantial saving of washing water is also obtained. In addition, the chemical reduction of indigo under nitrogen is total and perfect and leuco is broken down into particles of nanometric dimensions. This increased dyeing capacity of leuco allows for better penetration and better fixation thereof to the fiber compared to the traditional system, with different dyeing results in terms of fastness, intensity, corticality and lightness, differences that affect the final effects. Moreover, also in the dyeing of sulphur dyes, particularly of the black dye, this new technology has shown greater color rendering, with a significantly higher fixation degree and with better brightness compared to dyes made on traditional plants.
To most producers of denim fabrics, however, it is difficult to propose the combination of this new technology with the traditional dyeing technology with indigo. This not only for the considerable financial commitment and for the large space required, but also for the difficulties arising in production management with two different technologies. In practice, the producers of denim fabrics want to avoid installing dyeing plants with a particular production that, for the reasons above, may not always be used full time. Hence the need to devise a new dyeing technology in terms of new industrial, creative, economic and ecological needs, that require maximum operating flexibility, versatility, production change timeliness as well as management economy and ecological sustainability.
The disclosure provides a multifunctional continuous dyeing apparatus, in air or inert environment, with indigo or other dyes, of rope or flat warp chains for denim fabrics which can solve the above drawbacks of the prior art in an extremely simple, cost-effective and particularly rational and functional manner
In more detail, the disclosure provides a multifunctional dyeing apparatus that, in one or more samples, can be used in continuous dyeing processes with indigo and which allows carrying them out according to the traditional method, which is in contact with air, and alternatively also in an inert environment.
The disclosure further provides a multifunctional dyeing apparatus that is capable to reduce the number of the tanks normally used by the prior art plants, with the consequent economic advantages, but also able to operate so as to reduce scrap at each batch change.
The disclosure further provides a multifunction dyeing apparatus that is able to operate in an inert environment, allowing a significant reduction, in indigo dyeing, of the normal consumption of sodium hydrosulphite and caustic soda.
The disclosure also provides a multifunctional dyeing apparatus that allows dyeing in optimal technological conditions and that allows increasing the diffusion and fixation of the dye to the fiber.
The disclosure further provides a multifunctional dyeing apparatus that allows upgrading the traditional dyeing plants by including one or more multifunctional apparatuses that allow special dyeing, such as with black sulphur dye.
The disclosure generally provides a multifunctional continuous dyeing apparatus for yarn chains.
This multifunctional continuous dyeing apparatus in fact combines, in a simple and rational manner, the traditional technology of dyeing with indigo, carried out in contact with air, with the new dyeing technology in an inert environment, in its two different application methods, with all the relative advantages and benefits. Depending on the needs, this multifunctional continuous dyeing apparatus can alternatively employ air technology or that of two methods in nitrogen in a simple, cost-effective and environmentally friendly manner, taking advantage of the combination of their operational flexibility to produce all the wide range of items required.
The multifunctional continuous dyeing apparatus according to the present disclosure can also allow doubling the number of possible dyeing operations, by carrying out the same operations according to the “ring” system of patent GB 1430154. The teachings of patent GB 1430154 would however be applied with a single ring for a plurality of tanks and not with a plurality of rings in a single tank, thus obtaining the relative dyeing and economic advantages but annulling the defects that at the time did not allow the expansion of dyeing plants made according to the teachings of such a patent.
It should be noted that the application of the above “ring” system, besides the advantage of being able to halve the number of dyeing tanks used as the use thereof is doubled, also contributes a considerable dyeing improvement. The squeezing groups, operating on two overlapping yarn carpets and thus with a double linear density of threads, in fact guarantee greater residual uniformity of the dye bath, thus significantly mitigating the defect of the different shade of color between the central part and the lateral selvedges, as demonstrated in U.S. Pat. No. 4,118,183. In addition, the ring system, by halving the number of dyeing tanks with the relative groups of oxidation rollers, significantly reduces the amount of yarn threaded in the dyeing apparatus, thus facilitating the conduction of the apparatus and reducing to about a half the amount of yarn to discard at each batch change.
This ring system also adds a further series of technical and economic advantages because, again in relation only to the dyeing tanks, it halves the size, cost, installed power and volume of the dye bath. Ultimately, it is a system that helps making the multifunctional dyeing apparatus according to the present disclosure undoubtedly the most corresponding to all technological requirements and criteria of environmental sustainability.
The multifunctional continuous dyeing apparatus according to the present disclosure can also be provided with oxidation devices with variable and retrievable capacity as those described in the Italian patent application no. 102016000049954 on behalf of the same Applicant. The objective is to further reduce the amount of yarn that must be discarded at each batch change. Finally, the multifunctional continuous dyeing apparatus according to the present disclosure can work effectively with small batches of yarn, i.e. reduced yarn sizes, increasingly demanded by the market.
Substantially, the multifunctional continuous dyeing apparatus for yarn chains according to the present disclosure is designed to work with indigo or other dyes and is of the type provided with at least a first dyeing group, provided with a relative squeezing device, a central group designed for the oxidation of the dyed yarn, in the case of dye in the air, and/or designed for the diffusion/fixation of the dye in the fiber, in the case of dyeing under nitrogen. In addition, the apparatus is provided with a second dyeing group, divided into two parts that can be used simultaneously in the case of dye in the air and/or only the second part in the case of dye under nitrogen. This second dyeing group is also provided with a respective squeezing device. All groups of the dyeing apparatus are enclosed by an upper hermetically sealed covering case provided with large lateral windows, to be opened in the case of dyeing in the air, and with sealing devices for the exit of the yarn without loss of nitrogen.
The features and the advantages of a multifunctional continuous dyeing apparatus for a yarn chains according to the present disclosure will become apparent from the following exemplary and non-limiting description, made with reference to the accompanying schematic drawings, in which:
It is noted that in the following description and in the accompanying figures, numerous components, accessories and instruments normally supplied with this type of plants and apparatuses, such as inertisation, filling, discharge, heating, dye bath circulation, dehumidification devices etc. are not shown as they are well known to a person skilled in the art.
With reference to the figures, a multifunctional continuous dyeing apparatus for yarn chains is shown, according to the present disclosure, indicated as a whole with reference numeral 10. In particular, apparatus 10 is configured to dye rope or flat warp chains, for fabrics and is designed to work both with the indigo dye and with other dyes.
The dyeing apparatus 10 is provided at the bottom with a main body 12. Within the main body 12 are obtained in a sequence, with reference to the feeding direction F of a yarn 100, the following processing groups of such a yarn 100:
The dyeing apparatus 10 then comprises, downstream of the oxidation or diffusion/fixation group 18, at least a second dyeing group 20 of yarn 100, in turn provided with a relative second squeezing device 22 of such a yarn 100.
At least the first dyeing group 14, the first squeezing device 16, the oxidation or diffusion/fixation group 18 and the second dyeing group 20 are enclosed by at least an upper hermetically sealed covering case 24, integral with the main body 12. Each covering case 24 may be made integrally with the main body 12, or it may be removably fixed to the main body 12 through the interposition of seals 70.
At least part of the covering cases 24 is provided, on at least part of the lateral surfaces of such a covering case 24, with a plurality of doors 26 that open and are resealable. Doors 26 are to be opened in the case of dyeing in the air. The covering case 24 may also be provided with at least one outlet device or at least one outlet opening 28 for the yarn 100, through which said yarn 100 exits from the dyeing apparatus 10 in case of dyeing under nitrogen, while ensuring the sealed closure of the covering case 24.
As shown in
At the exit of the first dyeing tank 34, yarn 100 undergoes a first squeezing by passing between a pair of first squeezing rollers 38 of the first squeezing device 16. The first squeezing rollers 38 are the so-called squeezing “gadder”.
Downstream of the first squeezing device 16, yarn 100 is introduced into the oxidation or diffusion/fixation group 18. The oxidation or diffusion/fixation group 18 comprises a plurality of upper return rollers 40 and a plurality of lower return rollers 42. The upper 40 and lower 42 return rollers are configured to arrange yarn 100, which is in continuous movement, on a plurality of vertical planes.
In the configuration of the dyeing apparatus 10 of
Downstream of the oxidation or diffusion/fixation group 18, yarn 100 is introduced into the second dyeing group 20. The second dyeing group 20 comprises a respective second dye tank 44 into which yarn 100 is immersed, winding on a plurality of second return rollers 46.
The second dyeing tank 44 is internally provided with a wall 68, configured to divide said second dyeing tank 44 into two separate volumes 44A and 44B. Preferably, the first volume 44A is greater than the second volume 44B. In the case of dye in the air, both volumes 44A and 44B of the second dyeing tank 44 are filled with the dye bath and are used simultaneously. In the case of dyeing under nitrogen, the second volume 44B of the second dyeing tank 44 is arranged to contain a quantity of dye bath less than the quantity of dye bath contained in the first dyeing tank 34. At the exit of the second dyeing tank 44, yarn 100 undergoes a second squeezing by passing between a pair of second squeezing rollers 48 of the second squeezing device 22.
The oxidation or diffusion/fixation group 18 is provided with one or more respective oxidation intensifier devices 50, configured to generate a plurality of air flows that facilitate the oxidation process of the yarn 100. As shown in
In the configuration of the dyeing apparatus 10 of
In the configuration in
In detail, in the first dyeing group 14 of the first dyeing apparatus 10A, a first dyeing step of yarn 100 is carried out, followed by a squeezing step and an oxidation step in the oxidation or diffusion/fixation group 18 of such a first dyeing apparatus 10A. In the second dyeing group 20 of the first dyeing apparatus 10A, a second dyeing step of yarn 100 is then carried out, followed by a squeezing step and an oxidation step in an external path 66 interposed between the first dyeing apparatus 10A and the second dyeing apparatus 10B.
In the first dyeing group 14 of the second dyeing apparatus 10B, a third dyeing step of yarn 100 is then carried out, followed by a squeezing step and an oxidation step in the oxidation or diffusion/fixation group 18 of such a second dyeing apparatus 10B. In the second dyeing group 20 of the second dyeing apparatus 10B, a fourth dyeing step of yarn 100 is then carried out, followed by a squeezing step and a return step of such a yarn 100 to the first dyeing apparatus 10A through the return path 64. This return path 64 also has function of oxidizer.
The above process in air is then repeated at least once, thus obtaining a fifth, a sixth, a seventh and an eighth dyeing step of yarn 100, interspersed with respective squeezing and oxidation steps. This dyeing process is perfectly identical to the traditional one, which can be obtained for example in the eight dyeing tanks of the dyeing plant of known type shown in
In the configuration of
In detail, in the first dyeing group 14 of the first dyeing apparatus 10A, a first dyeing step of yarn 100 is carried out, followed by a squeezing step and a diffusion/fixation step of the dye on such a yarn 100 in the oxidation or diffusion/fixation group 18 of such a first dyeing apparatus 10A. In the second dyeing group 20 of the first dyeing apparatus 10A, a second dyeing step of yarn 100 is then carried out (with short threading in the second volume 44B of the second dye tank 44 only, i.e. with a shorter threading than the maximum threading that yarn 100 can have throughout the second dyeing group 20), followed by a squeezing step and an oxidation step in an external path 66 exposed to air and interposed between the first dyeing apparatus 10A and the second dyeing apparatus 10B.
In the first dyeing group 14 of the second dyeing apparatus 10B, a third dyeing step of yarn 100 is then carried out, followed by a squeezing step and a diffusion/fixation step of the dye on such a yarn 100 in the oxidation or diffusion/fixation group 18 of such a second dyeing apparatus 10B. In the second dyeing group 20 of the second dyeing apparatus 10B, a fourth dyeing step of yarn 100 is then carried out (again with short threading in the second volume 44B of the second dyeing tank 44 only), followed by a squeezing step and a return step of such a yarn 100 to the first dyeing apparatus 10A through the return path 64. This return path 64 also has function of oxidizer.
The above process under nitrogen may then be repeated at least once, thus obtaining a fifth, a sixth, a seventh and an eighth dyeing step of yarn 100, interspersed with respective diffusion/fixation and oxidation steps. With the dyeing plant in the configuration of
In the configuration of
In detail, in the first dyeing group 14 of the first dyeing apparatus 10A, a first dyeing step of yarn 100 is carried out, followed by a squeezing step and a diffusion/fixation step of the dye on such a yarn 100 in the oxidation or diffusion/fixation group 18 of such a first dyeing apparatus 10A. Yarn 100 then comes out from the first dyeing apparatus 10A to undergo an oxidation step in an external path 66 exposed to air and interposed between the first dyeing apparatus 10A and the second dyeing apparatus 10B.
In the first dyeing group 14 of the second dyeing apparatus 10B, a second dyeing step of yarn 100 is then carried out, followed by a squeezing step and a diffusion/fixation step of the dye on such a yarn 100 in the oxidation or diffusion/fixation group 18 of such a second dyeing apparatus 10B. Yarn 100 then comes out of the second dyeing apparatus 10B to be returned until the first dyeing apparatus 10A through the return path 64. This return path 64 also has function of oxidizer.
The above second process under nitrogen may then be repeated at least once, thus obtaining a third and a fourth dyeing step of yarn 100, interspersed with respective squeezing, diffusion/fixation and oxidation steps. With the dyeing plant in the configuration of
It should be noted that the ring system provided with the return path 64, compared to patent GB 1430154, is conceptually and technically applied differently. In fact, in addition to the dyeing processes described above, other variations are possible depending on the number of dyeing apparatuses 10 used, which can be one or even more than two. Of course, the indicative cycles of the dyeing processes above can be integrated with traditional manufacturing operations of denim fabric, such as caustic soda pre-treatment, pre-dyeing, over-dyeing, etc.
It is also noted that each covering case 24, and consequently the shape and the capacity of the two dyeing groups 14 and 20 (which may comprise one or more dyeing tanks 34, 44) and of the intermediate oxidation or diffusion/fixation group 18 can be achieved in various ways according to the production or dyeing requirements. Therefore, a minimum or higher content of yarn 100 may be employed for dyeing and/or the diffusion/fixation and/or the oxidation of the dye, with or without the nitrogen seal outlet device 28 to make such a yarn 100 exit from the dyeing apparatus.
By way of example, some of these possible variations of the dyeing apparatus 10, which all fall under the protection scope of the disclosure, are shown in the accompanying
It has thus been seen that the multifunctional continuous dyeing apparatus for warp chains according to the present disclosure achieves the objects described above. The multifunctional continuous dyeing apparatus for warp chains according to the present disclosure achieves the objects mentioned in the preamble of the description and, unlike the plants and processes used to date in dyeing with indigo, not only has greater operating flexibility but also allows significantly reducing the number of treatment tanks and, consequently, the costs of plants, the installed power, the volumes of the dyeing baths as well as production waste during batch changes.
In case of use for dyeing in an inert environment, it should be noted that in order to have maximum flexibility over the end result in terms of corticality and fixation degree, in addition to the known physical and chemical variables, the apparatus above is also arranged to vary the bath-fiber contact time and the residence time in the diffusion/fixation group. The multifunctional dyeing apparatus according to the present disclosure further offers the possibility to dye small yarn batches, i.e. reduced yarn sizes, increasingly demanded by the market. It is in fact noted that in traditional plants, the minimum length of warp batches to dye is based on the length of the yarn which is the threading of the plant itself and, therefore, at every batch change the percentage of yarn to discard will be proportionately higher the shorter will be the batch.
The multifunctional continuous dyeing apparatus for warp chains of the present disclosure thus conceived can be subjected to numerous modifications and variants, all falling within the same inventive concept; moreover, all details may be replaced with technically equivalent elements. In the practice, the materials used as well as shapes and sizes, may be any, according to the technical requirements.
The scope of protection of the disclosure is therefore defined by the accompanying claims.
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|---|---|---|---|
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| Filing Document | Filing Date | Country | Kind |
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| PCT/IB2017/053151 | 5/29/2017 | WO |
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| WO2017/208134 | 12/7/2017 | WO | A |
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| CN Office Action dated Jun. 5, 2020 re: Application No. 201780025584.X, pp. 1-22, citing: CN101107393A, CN2832846Y, CN1242059A and CN201183344Y. |
| EP Examination Report dated Mar. 11, 2020, pp. 1-7. citing: US 2008/040870 A1, U.S. Pat. No. 5,942,006 A and WO 01/74481 A1. |
| International Search Report for corresponding application PCT/IB2017/052845 filed May 15, 2017; dated Sep. 6, 2017. |
| International Search Report for corresponding application PCT/IB2017/053151 filed May 29, 2017; dated Aug. 29, 2017. |
| Written Opinion of the International Searching Authority for corresponding application PCT/IB2017/052845 filed May 15 2017; dated Sep. 6, 2017. |
| Written Opinion of the International Searching Authority for corresponding application PCT/IB2017/053151 filed May 29, 2017; dated Aug. 29, 2017. |
| JP Office Action dated Jan. 7, 2021, re: Application No. 2018-555591, pp. 1-4, citing: CN1045320501, JPS46-038631A, JPH10-046466A, JP2001-518989A, JP2002-281136A, U.S. Pat. No. 6355073, CN1165646. |
| JP Office Action dated Jan. 7, 2021 re: Application No. 2018-554703, pp. 1-4, citing: JP2008-508437A, JP2009-523200A, JPS62-257480A, JP2002-061068A, U.S. Pat. No. 5337586, US2009/0000042, CN101389801. |
| Number | Date | Country | |
|---|---|---|---|
| 20200299896 A1 | Sep 2020 | US |
