Patent Application
20210002822
This application is related to and claims priority benefits from Europe Patent Application No. 19315057.0 (“the '570 application”), filed on Jul. 4, 2019. The '570 application is hereby incorporated in its entirety by this reference.
The present invention relates to the field of the textile industry, and more particularly to the field of treating yarns by dyeing.
In the context of an industrial production of yarns for textile use, one essential operation that partly conditions its marketing relates to the step of coloring the yarn by dyeing it. The yarn is configured to be moved axially between two bearings such that the movement axis of the yarn crosses an ink jet intended to color it in a controlled manner. Currently, the deposition of the ink is carried out in the form of a continuous ink jet sprayed by a nozzle. The moving textile yarn passes through the ink jet. According to one exemplary embodiment, controlling the deposit of ink on the yarn involves a mechanism of periodic deflection of the ink jet with respect to the moving yarn when certain segments of the yarn are not intended to be dyed. The ink deflected so as not to dye the yarn is then recovered.
Although such a mechanism makes it possible to perform a controlled deposition of dye on the yarn with a movement speed of the yarn on the order of 600 meters per minute, it has the drawback of requiring that a large volume of dye be sprayed so that the yarn is colored over its entire section.
The present invention aims to address these drawbacks by proposing a dyeing mechanism for a textile yarn that makes it possible to reduce the consumption of dye necessary for dyeing a yarn while allowing movement of the yarn at speeds of more than 500 meters per minute.
The invention therefore relates to a device for dyeing a yarn driven in movement, characterized in that the device comprises:
The invention also relates to a method for dyeing a yarn using a device according to the invention, characterized in that the method comprises:
The invention will be better understood from the following description, which relates to preferred embodiments, given by way of nonlimiting examples, and explained with reference to the appended schematic drawings, in which:
The invention relates to a device 1 for dyeing a yarn 2 driven in movement, characterized in that the device 1 comprises:
The expression “surface of a yarn portion” should be understood as referring to a part of the peripheral surface corresponding to a length of an arc on the order of 180° centered on the axis of the yarn 2 and along a length of the yarn 2 along the axis of the yarn 2. Thus, during a movement along a substantially horizontal axis or along an axis forming an incline relative to the vertical, the yarn 2 comprises a yarn portion surface that is greater, that is to say oriented substantially upward, at which a deposition nozzle 4, 5 is capable of depositing an amount of liquid dye.
The dyeing device according to the invention is thus configured to perform two successive dye deposits on each of the opposite faces of a same length portion of the yarn 2 by causing an axial pivoting of the yarn 2. The successive positioning of a different face of the yarn 2 in front of a respective deposition nozzle 4, 5 makes it possible to deposit dye on different surfaces of the same length portion of the yarn 2. The inventive device is configured to allow the axial pivoting of the yarn 2 moving between the two deposition nozzles 4, 5. According to one preferred implementation of the inventive device, only a limited amount of dye is deposited by the first nozzle 4 on the first surface of the yarn 2, so that the thickness of the yarn 2 is not impregnated with the dye and that, by gravity and under the imbalanced weight of the dye deposited on the first upper surface of the yarn 2, the yarn 2 pivots axially by placing the first colored surface, initially upper, in the lower position and simultaneously pivots the second blank surface, initially lower, in the upper position.
According to a particular construction example of the device, the coloring of a length portion of the yarn 2 only requires depositing dye volumes strictly suited to the surfaces to be dyed. Indeed, while in the devices of the prior art, the coloring of a yarn length portion involves depositing dye at a first surface so that the dye passes through the thickness of the yarn to also color the surface of the yarn opposite the second surface, the inventive device allows the dye to be deposited at each opposite face of a length portion of the yarn 2 without requiring the presence of dye in the thickness of the yarn 2. Also, in the context of a device 1 according to the invention, the volume of dye necessary to dye a length portion of the yarn 2 is less than that used in the context of a device of the prior art. This difference in required volume makes it possible to save dye by avoiding unnecessary coloring of the internal thickness of the yarn 2.
According to another particular construction example, complementary to the previous particular example, the first nozzle 4 and the second nozzle 5 are supplied with liquid dye by a common supply line 3. This arrangement makes it possible to deposit, by each of the nozzles 4, 5, the same color on each of the opposite faces of the thickness of the yarn 2. Furthermore, this arrangement also makes it possible to obtain a uniform pressure at the liquid dye moving in the supply line 3, so that the jet of dye obtained at each of the nozzles 4, 5 is substantially identical.
According to another particular construction example, complementary to the various previous specific examples, the device 1 comprises a mechanism for managing the pressure of the liquid dye near at least one deposition nozzle 4, 5. This mechanism for managing the pressure of the liquid dye positioned on a part of the dye supply line 3 in particular allows a reduction in the pressure at the deposition nozzle 4, 5 so that the quantity of dye sprayed by the deposition nozzle 4, 5 is reduced in proportion. The pressure management mechanism thus makes it possible to manage the quantity of dye sprayed and to obtain an adjustable deposit of dye on the surface of the yarn 2.
According to a specific feature of this other particular construction example, the pressure management mechanism comprises at least one dye ejection nozzle 7. This dye ejection nozzle 7, positioned on a part of the dye supply line 3, for example near a deposition nozzle 4, 5, is controlled to reduce the pressure at the supply line by decreasing the quantity of dye present in the supply line 3. The actuation of the opening of this ejection nozzle 7 is controlled by a control unit 10. This control unit 10 can be connected to at least one sensor for the dye pressure inside the associated supply line 3. This control unit 10 is preferably designed to manage the internal pressure of the associated line 3 automatically. According to a complementary preferred construction, the control unit 10 operates under the control of a programmed interface that predefines the quantity of dye to be deposited at least at a portion of the treated yarn 2. Since the treated yarn 2 is in continuous motion, the quantity of dye to be deposited at a defined portion is then calibrated as a function of the pressure of the dye inside the associated line 3. In fact, the higher the pressure inside the supply line 3, the greater the quantity of dye sprayed at the deposition nozzle 4, 5. The pressure exerted by the dye inside the supply line 3 is generated by the continuous operation of a supply pump positioned upstream from the supply line 3. Also, when the deposition 4, 5 or ejection 7 nozzles are closed, the pressure inside the supply line increases. According to an alternative preferred construction feature, the dye supply flow from the pump is greater than the dye outlet flow at the set of deposition nozzles 4, 5 associated with the supply line 3, so that an operation of the deposition nozzles 4, 5 with a permanent opening when no ejection nozzle 7 is open also allows an increase in the pressure inside the supply line 3. The dye supply flow by the pump is also calibrated so that the opening of an ejection nozzle 7 performs a withdrawal of dye from the supply line 3 that is sufficient to reduce the pressure and/or increase this pressure generated by the continuous operation of the supply pump. According to a preferred construction, the adjustment of the pressure inside the supply line 3 involves several ejection nozzles 7 arranged at the same supply line 3 and controlled by the control unit 10 so that, by opening/closing only one of the ejection nozzles 7 or several ejection nozzles 7 simultaneously, the internal pressure of the supply duct 3 is able to be adjusted more finely, but also more quickly. Alternatively or additionally, the adjustment of the internal pressure of the supply line 3 involves one or more variable-flow ejection nozzles 7. These variable-flow ejection nozzles 7 for example incorporate a diaphragm that adjusts the opening of the orifice of the ejection nozzles 7 as a function of the desired dye flow. Also, managing the pressure of the dye inside the associated line 3 via the control unit 10 allows an adjustment of the quantity of dye ejected at the deposition nozzle 4, 5 and intended to be deposited on the moving yarn 2. According to a specific embodiment of this feature, the control unit 10 operates in association with the synchronization mechanism 6 of the successive actuation of each of the deposition nozzles 4, 5 of the device. According to an additional specific feature, this control unit 10 is integrated into the synchronization mechanism 6 of the actuation.
According to another particular construction example, complementary to the various previous specific examples, the device 1 comprises a mechanism for axial pivoting of the yarn 2. According to an exemplary embodiment, this pivoting mechanism involves controlling the tension of the yarn moving between the two deposition nozzles 4, 5 such that the traction produced on the yarn as part of its movement does not generate too great a tension on the yarn likely to prevent its axial pivoting. According to another exemplary embodiment, this pivoting mechanism comprises an interface for unbalancing the first colored surface of the yarn 2, so that the yarn 2 pivots axially under the effect of the weight of the deposited dye. According to another exemplary embodiment, this pivoting mechanism comprises an interface for driving the axial rotation of the yarn 2 about its own axis. It should be noted that the pivoting mechanism integrated into the inventive device can be made by one or a combination of these exemplary embodiments of the pivoting mechanism.
According to another particular construction example, complementary to the various previous specific examples, the dyeing device 1 comprises:
According to another particular construction example, which is complementary to the various previous specific examples, at least one deposition nozzle 4, 5 is associated with a mechanism 9 for interrupting the spraying of dye comprising at least one interface for deflecting the jet of dye sprayed toward a receiving tray. This mechanism 9 for interrupting the spraying of dye onto the moving yarn 2 makes it possible to maintain a constant flow of liquid dye sprayed by the deposition nozzle 4, 5 while spreading the sprayed jet of dye relative to the moving yarn 2. This mechanism 9 for interrupting the spraying by deflection of the jet thus authorizes an interruption in the deposition of liquid dye for a reduced time interval, on the order of 2 milliseconds. This mechanism thus allows precision in the deposition on the one hand, and in the absence of dye deposition on a yarn 2 moving at a speed on the order of 600 meters per minute on the other hand. Preferably, the mechanism 9 for interrupting the spraying of each of the deposition nozzles 4, 5, 4′, 5′ is associated with the mechanism 6 for synchronizing the actuation of the nozzles 4, 5, 4′, 5′. This synchronization mechanism 6 thus plays a role, in cooperation with the different nozzles 4, 5, 4′, 5′ that it actuates, in distributing one or more dyes along the length of the moving yarn 2. This synchronization mechanism 6 preferably operates under the control of a programmed interface that predefines the desired coloring for at least a portion of the treated yarn 2.
According to a preferred arrangement of the device 1 according to the invention, the liquid dye sprayed outside the supply line 3 by a deposition nozzle 4, 5, 4′, 5′ or by a dye ejection nozzle 7, 7′ and which is not deposited on a surface of the yarn 2, is recovered at a dedicated interface to be reused, or even reinjected into the supply line 3.
The invention also relates to a method for dyeing a yarn using a device 1 according to the invention, characterized in that the method comprises:
According to a particular embodiment feature of the inventive method, the method comprises at least one step of depositing a dye using a deposition nozzle 4, 5 correlated with a step of opening a dye ejection nozzle 7 upstream from the deposition nozzle 4, 5 so as to control the quantity of dye sprayed by the deposition nozzle 4, 5.
Of course, the invention is not limited to the embodiments described and shown in the accompanying drawings. Modifications remain possible, in particular from the point of view of the constitution of the various elements or by substitution of technical equivalents, without departing from the scope of protection of the invention.
| Number | Date | Country | Kind |
|---|---|---|---|
| 19315057.0 | Jul 2019 | EP | regional |
