Oxidation intensifier device for indigo dyeing systems

Abstract

An oxidation intensifier device for a continuous dyeing system for dyeing a warp thread, the device arranged for being mounted in the oxidation assembly of the dyeing system and comprises two blowing assemblies having a substantially identical shape and opposed one another, each blowing assembly is provided with at least one respective fan and, downstream of such a fan, with a respective plurality of convergent conduits arranged along development directions that are parallel and transversal to the feeding direction of the warp thread, the convergent conduits of a first blowing assembly converge in a opposite direction with respect to the convergence direction of the convergent conduits of the opposite blowing assembly, each convergent conduit is configured to face parallel to a single lap of the warp thread moving inside the dyeing system and is provided with a plurality of longitudinal slots oriented along the same development direction of the respective convergent conduit, where each fan is hydraulically connected to the plurality of convergent conduits of the respective blowing assembly and is configured to convey air towards the plurality of longitudinal slots, so that a plurality of opposite air laminar flows is generated, which generate a plurality of turbulences adapted to facilitate the oxidation process of the dyed warp thread on both its surfaces.

Claims

1. Oxidation intensifier device for a continuous dyeing system for dyeing a warp thread, the device being arranged for being mounted in an oxidation assembly of the dyeing system and comprising two blowing assemblies having a substantially identical shape and being opposed one another, each blowing assembly being provided with at least one respective fan, the device being wherein: each blowing assembly is provided, downstream of the respective fan, with a respective plurality of convergent conduits arranged along development directions that are parallel and transversal to the feeding direction of the warp thread in the dyeing system; the convergent conduits of a first blowing assembly converge in a opposite direction with respect to the convergence direction of the convergent conduits of the opposite blowing assembly; each convergent conduit is configured to face parallel to a single lap of the warp thread moving inside the dyeing system; each convergent conduit is provided with a plurality of longitudinal slots, that are oriented along the same development direction as of the respective convergent conduit; each fan is hydraulically connected to the plurality of convergent conduits of the respective blowing assembly and is configured to convey air, which has been drawn from the environment where the dyeing system operates, towards the plurality of longitudinal slots, a plurality of opposite air laminar flows being generated through said longitudinal slots, said opposite air laminar flows generating a plurality of turbulences adapted to facilitate the oxidation process of the dyed warp thread on both its surfaces; at least a part of the convergent conduits is provided with respective shutters placed at the respective longitudinal slots; and the device comprises an electronic control system configured to dynamically adjust, in real time, through the operating parameters of the fans, the air speed and flow rate to be blown on the warp thread, said electronic control system being further configured to control the opening and closing of the longitudinal slots of said convergent conduits through the respective shutters.

2. Device according to claim 1, wherein the convergent conduits are arranged equally spaced from one another.

3. Device according to claim 1, wherein each fan is an axial fan.

4. Device according to claim 3, wherein each fan is an axial ducted fan.

5. Device according to claim 1, wherein each fan comprises at least one of a centrifugal fan, an axial fan and a mixed-flow fan.

6. Device according to claim 3, wherein said fan provided with each blowing assembly is configured to suck and release air along a direction which is perpendicular to the development direction of the respective convergent conduits.

7. Device according to claim 6, wherein at least one conveying chamber is interposed between the fan and the convergent conduits of each blowing assembly, said chamber being configured to deviate the air flow by an angle of 90.

8. Device according to claim 3, wherein said fan provided with each blowing assembly is configured to suck and release air along a direction which is parallel to the development direction of the respective convergent conduits.

9. Device according to anyone of the preceding claims, wherein each fan is provided with a respective filter configured to remove any solid particles from the air entering the convergent conduits.

10. Device according to claim 9, wherein the filter is arranged upwards of the blades of the respective fan.

11. Device according to claim 1, wherein each convergent conduit has a rectangular cross-section, where the long side of the rectangle of the convergent conduit of a first blowing assembly faces in a parallel way both the surface of the warp thread and the corresponding long side of the rectangle of the convergent conduit of the opposed blowing assembly.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The features and the advantages of an oxidation intensifier device for indigo dyeing systems 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:

(2) FIG. 1 is a schematic view of a generic dyeing system provided with two dyeing/squeezing assemblies, between which an oxidation intensifier device according to the present disclosure is arranged;

(3) FIG. 2 is a detailed view of an enlarged detail of FIG. 1;

(4) FIG. 3 shows an oxidation intensifier device according to the present disclosure installed on a generic dyeing system;

(5) FIG. 4 is a perspective view of the oxidation intensifier device of FIG. 3; and

(6) FIG. 5 is a perspective view of a part of the oxidation intensifier device of FIG. 3, which shows the development of the convergent conduits and of the respective longitudinal slots.

DETAILED DESCRIPTION

(7) With reference in particular to FIG. 1, the oxidation intensifier device according to the present disclosure, generally indicated with reference numeral 10, is installed in the space between two dyeing/squeezing assemblies 102 and 104 of a continuous dyeing system for threads, in particular a system which operates according to the open width dyeing system. Each of the dyeing/squeezing assemblies 102 and 104 comprises a respective impregnation vat 106 in which a warp thread 100, which advances in the direction of the arrows indicated in FIG. 1, is introduced in a dye bath. The dye bath may consist, for example, of an alkaline solution of indigo dye.

(8) The warp thread 100 arrives in each vat 102 and 104 passing over a respective guide roller 108 and is then immersed in the vat itself by twisting on a plurality of return rollers 110. At the exit of each vat 102 and 104, the warp thread 100 undergoes a squeezing by passing between a pair of squeezing rollers 112.

(9) The oxidation of the warp thread 100 is carried out in the area of the dyeing system interposed between the pair of squeezing rollers 112 at the outlet of a first vat 102 and the guide roller 108 associated with the next vat 104. In this oxidation assembly or area, downstream of a suitable movable tensioning roller 114 for tensioning the warp thread 100 and for the synchronism of the drive motors of the squeezing cylinders 112 of the two vats 102 and 104, a plurality of return rollers 116 is provided, configured to arrange the warp thread 100, which is in continuous movement, on a plurality of vertical planes parallel to each other (see FIG. 3), so as to increase the surface thereof exposed to air.

(10) The oxidation intensifier device 10 is mounted in the system dyeing zone in which oxidation of the warp thread 100 is carried out, i.e. in the oxidation assembly of the dyeing system itself. As shown in FIG. 4, such an oxidation intensifier device 10 consists of two blowing assemblies 12 and 14 having a substantially identical shape and opposed one another.

(11) Each blowing assembly 12 and 14 is provided with at least one respective fan 16 and 18, preferably an axial fan and even more preferably a ducted axial fan. It is however not excluded that each fan 16 and 18 may be of a different type, such as a centrifugal fan, an axial fan or a helico-centrifugal fan. It is not even excluded that each blowing assembly 12 and 14 can be provided with a plurality of fans different from one another.

(12) Each blowing assembly 12 and 14 is further provided, downstream of the respective fan 16 and 18, with a respective plurality of convergent conduits 20 and 22, preferably arranged equally spaced from each other and along development directions that are transversal to the feeding direction of the warp thread 100 in the dyeing system. As shown in FIG. 4, although being arranged along parallel development directions, the convergent conduits 20 of a first blowing assembly 12 converge in a opposite direction with respect to the convergence direction of the convergent conduits 22 of the opposite blowing assembly 14.

(13) Each convergent conduit 20 and 22 is configured to face parallel to a single vertical lap of the warp thread 100 moving inside the dyeing system and is in turn provided with a plurality of longitudinal slots 24, i.e. oriented along the same development direction of the respective convergent conduit 20 and 22 (see FIG. 5). Each fan 16 and 18 is hydraulically connected to the plurality of convergent conduits of the respective blowing assembly 12 and 14 and is configured to convey air, taken from the environment in which the dyeing system works, towards the plurality of longitudinal slots 24. In this way, a plurality of opposite air laminar flows is generated through the longitudinal slots 24 of the two separate blowing assemblies 12 and 14, which in turn generate a plurality of turbulences adapted to facilitate the oxidation process of the dyed warp thread 100 on both its surfaces.

(14) In detail, based on the embodiment example of the oxidation intensifier device 10 shown in the figures, each blowing assembly 12 and 14 is provided with a single fan 16 and 18 configured to suck and release air along a direction which is substantially perpendicular to the development direction of the respective convergent conduits 20 and 22. At least one conveying chamber 26 and 28 is interposed between fan 16 and 18 and the convergent conduits 20 and 22 of each blowing assembly 12 and 14 which, in the specific embodiment example shown in the figures, is configured for deviating the air flow by an angle of about 90.

(15) In any case, conveying chambers having a different shape may be provided, configured for deviating the air flow according to different methods depending on the construction and size requirements of the dyeing system. For example, each fan 16 and 18 may be directly mounted on the front head of the respective conveying chamber 26 and 28 in such a way as to be configured to suck and release air along a direction which is substantially parallel to the development direction of the respective convergent conduits 20 and 22.

(16) Each fan 16 and 18 may be provided with a respective filter 30 and 32, preferably arranged upstream of the blades of fan 16 and 18 itself, configured to remove any solid particles from the air entering the convergent conduits 20 and 22. This prevents dirt and various impurities from being blown on the warp thread 100 as these could adversely affect the dyeing steps.

(17) Each convergent conduit 20 and 22 preferably has a rectangular cross-section, where the long side L of the rectangle of the convergent conduit 20 of a first blowing assembly 12 faces parallel both to the surface of the warp thread 100 and to the corresponding long side L of the rectangle of the convergent conduit 22 of the opposite blowing assembly 14 (see enlarged detail in FIG. 2). This reduces the transverse dimensions (with reference to the feeding direction of the warp thread 100 in the dyeing system) of the entire oxidation intensifier device 10, while allowing a smooth movement of the warp thread 100 in the interstices present between the various convergent conduits 20 and 22 facing each other. In this way, a mutual spacing of the return rollers 116 is not required as compared to the traditional configurations of the dyeing systems. It is however not excluded that the cross section of the convergent conduits 20 and 22 may be of other shape, provided it is compatible with the air speed and flow rate to be blown onto the warp thread 100, as well as with the technical and dimensional features of the dyeing system.

(18) The air speed and flow rate to be blown onto the warp thread 100 are adjusted dynamically and in real time by an electronic control system 36, which can be installed both on the oxidation intensifier device 10, and on the dyeing system as part of the control electronics of the dyeing system itself. In particular, the electronic control system 36 is configured both to adjust the operating parameters of fans 16 and 18 and to control the opening and closing of the longitudinal slots 24 of the convergent conduits 20 and 22.

(19) The opening and closing of the longitudinal slots 24 is controlled by the electronic control system 36 and is carried out through respective shutters 34 with which at least a part of the convergent conduits 20 and 22 is provided at the respective longitudinal slots 24. The quantitative variation of the air flow dispensed by the oxidation intensifier device 10 therefore affects the air/yarn interchange time, allowing the dyeing system to be adapted to the specific features of the various dyeing processes.

(20) The oxidation intensifier device for indigo dyeing systems 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.