EP0133897A1 - Method and apparatus for drying textile materials in rope form - Google Patents

Abstract

In practice, for economic reasons there is an urgent need to be able to carry out the drying of moist textile goods immediately after a completed wet treatment in the same device in which the previous treatment operation has also taken place. According to the invention, in the case of product lines guided on jet systems, the problems which arise are solved in that when using nozzle systems to be operated with liquor, steam or hot air flow for the product advance, the goods transport taken over by the gaseous agent after the wet treatment has been completed, which comes under a predetermined statistical overpressure on the strand-like textile material to effect evaporation drainage of the same, then the moisture absorbed by the circulating drive gas is condensed by cooling and the circulated air is dried again.

Description

The present invention relates to a method for pre-drying or drying textile web or knitted fabrics in strand form, as well as a device which is suitable for this and which works according to the jet principle and which also ensures the feed of the fiber material through the system.

From the published European patent application EP-A-00 14 919 it is known to subject textile fabric strands in jet piece dyeing plants to a wet finishing, in particular for dyeing. In this process, the textile material, which is combined into a strand and passed past the nozzles, is either circulated using the treatment liquor circulating in the same direction via the nozzle system, or the locomotion is carried out by means of a gas stream or steam-air directed from the nozzles under excess pressure onto the fiber material Mix. The main feature of this working technique is therefore that the goods are conveyed through the unit repeatedly in the continuous form through the kinetic energy imparted by the jet during tangential application. Although gas and liquid flow can be alternated or combined in accordance with the process control for the drive of the strand during the different treatment stages, which allows a seamless transition from one dyeing step to another without a standstill and under isothermal conditions, it was previously relied on for the drying of the wet-treated textile material in this way interrupting the spraying and thus the operation and, after removing the goods from the dyeing jet, performing the drying operation on a separate system of the usual type.

In the apparatus area, the drying of the textile goods after the wet finishing represents an essential process step. Basically, drying facilities are to be aimed at, with which the goods can be dried in the same presentation form in which the wet finishing was also carried out.

DE-OS 30 46 292 describes a process for drying textile goods in web form, according to which the moist goods are passed within a boiler that is sealed from the outside atmosphere during the continuous passage through several pipe section sections arranged one behind the other and thereby in a broad form of action is exposed to a stream directed longitudinally thereon from a pressurized steam-air mixture. In addition, for special purposes there is the possibility of discontinuous drying of sheet-like piece goods with batch loading of the dryer, for which so-called tumblers, i.e. Rotating drums are considered, in which the dry material is whirled around without tension and without pressure and the desired effect is achieved due to the intensive mechanical movement.

If, on the other hand, the material to be dried is anchored on a material carrier, there are various drying systems available, such as through-flow dryers ^* , which also differ in the type of heat supply to the textile material and the elimination of moisture. A rapid and at the same time intensive drying is usually made possible when, for example, when treating yarn that is wound on packages or is similarly compactly attached, a stream of warm air penetrates the material pack radially.

The effectiveness of such a discontinuous drying can be supported by the process ^* or chamber dryer carried out under the influence of reduced pressure. The advantage of the vacuum, by increasing the boiling temperature to increase the rate of evaporation, can only be used to a limited extent in through-flow dryers in which the air is constantly sucked through the textile material, since an intensive exposure of the winding body to heat via the inflowing warm air due to the Vacuum present lower density cannot be achieved. According to the technology described in DE-AS 19 02 306 and DE-AS 1'9 27 651, the evacuation phase is therefore separated from the heating phase.

In the case of the through-flow dryer, however, the use of superatmospheric pressure conditions can also be used. Since in this embodiment - in contrast to drying under normal pressure - the drying air circulates in a closed system, the heat contained in the exhaust air from the drying zone is not lost, which is noticeable in a higher heat supply to the winding former with the same fan power. As a result of the larger amount of heat in the air flow before entering the dry material, a higher degree of moisture in the exhaust air is achieved with the pressure dryer. This is advantageously used for yarn spools in the process according to DE-OS 26 16 280.

In both vacuum drying and pressure drying, the respective measures can take place in the same vessel as the wet finishing.

The object of the present invention is now to develop a drying technique specially tailored to the needs of devices operating according to the jet principle, so that the wet finishing together with the subsequent dewatering can be carried out in one go, without the goods running underneath must be broken and the time and thermal energy losses occurring due to the inevitable change of the system can be avoided or there is no loss in quality of the goods treated as a result of the additional loading operation.

Experience in the field of steam-operated nozzle systems in accordance with the European patent application EP-A-00 14 919 mentioned at the beginning has shown that this gives good spread of goods and has shown that, due to the high exit velocity, such a nozzle jet is in a pressurized state Circulation of the moist goods snatches enough water, so this flow concept can be used for drying or partial drying of the textile goods.

The present invention thus relates to a process for the partial or complete drying of batches of goods made of textile fabrics or knitted fabrics discontinuously circulating in endless form in jet piece dyeing systems following a wet treatment operation for textile finishing according to the pull-out technique, wherein the feed for the transport of the fiber material within the operates in a self-contained system via the actuation of the nozzle system, characterized in that evaporation drainage of the same to a specific one takes place immediately after the wet refinement and after the treatment liquid has been drained off from this previous processing step in the course of the movement of the wet-refined moist goods strand that has now been taken over and maintained by a gas stream Residual moisture content when meeting and flowing around with the circulated in the same apparatus arrangement via a separate circuit connected to one before given excess pressure compressed drive gas, preferably steam Air mixture, followed by cooling of the gas mixture resulting from the previous measure as exhaust air from a supersaturated to a dry-saturated state with simultaneous recondensation of the moisture extracted from the textile material and separation of the latter from the circuit of the gaseous drying agent.

In the foreground of the advantages that can be achieved by the novel method of working is the fact that after wet finishing in the same machine unit, predrying or drying of the bleached and / or dyed and / or finished goods strand can be carried out immediately afterwards. According to the invention, no independent pressure dryer is required, but it is sufficient to provide an existing jet dyeing machine with a few additional devices. Additional machine units are therefore unnecessary. Because the refined material remains in the previously used apparatus, an enormous amount of time can be saved. Retrofitting is no longer necessary. Because drying takes place in the closed jet dyeing machine, there is also a much more favorable energy balance, especially since the heat of evaporation for the moisture to be evaporated can be recovered as the heat of condensation of the water separated in the circuit from the exhaust air due to the closed system, which is not insignificant Amounts of such condensate occur.

However, there are also some not insignificant improvements with regard to the textile technological properties when using the method according to the invention. Taking into account the fact that the strand of goods is moved quickly during drying, the fiber relaxes, which results in a very favorable handle and fullness of the material. That way you can under certain circumstances, softening agents such as plasticizers, fillers and the like can be saved. A particular advantage of the invention is that the goods are laid with each circulation so that no folds can form.

The idea of the invention on which the claimed method is based is based on the fact that the gaseous drive means which provides the advance of the goods is exploited for the purpose of dewatering, as it were, as a pressure dryer. In such a function, the drying medium controlled in the recirculation mode - as in the case of pure goods transport - is guided tangentially to the direction of travel with simultaneous flow around the strand-like textile material, the drying process as such - depending on the air speed and the type of moisture binding to the substrate - both by mechanical dewatering Swirling and separation as well as thermal measures for the evaporation of the material moisture include.

The heat required to heat the textile material running in the form of a strand is preferably taken from a steam-air mixture. This desiccant flows in a closed system in a circuit which is started by the power of a blower and is compressed by the blower to the back pressure caused by the air volume. The delivery head, ie the total pressure difference which the compressor has to overcome, corresponds to the sum of all resistances for an intended gas volume when flowing through the circulation system including the goods. Since the present invention relates to evaporation drying, the steam-air mixture is supplied with thermal energy via an air heater in order to achieve the desired drying speed, in addition to the application of kinetic energy via the compression work. This is on the pressure side of the compressor in the circuit built-in. The heat is given off to the continuously moving textile goods mainly within the nozzle section and the downstream transport section, on which the goods are accompanied by the gaseous heating medium. Adequate contact between the drying air and the strand of goods is ensured by the fact that the material to be dried, which is not specially laid out, is a quasi-open surface with corresponding free spaces. A more extensive penetration of the strand-like article with the drying air is then further promoted by a certain loosening of the packing density of the goods after passage of the nozzle in the course of the subsequent path through the drying zone. Inside the textile, moisture is transported to the outer areas initially due to capillary forces and in the further drying stage via vapor diffusion, as there is a difference in moisture and temperature from the surface at this point. The impulse for the forward movement of the textile material, ie the circulation of goods, which is caused by the gas flow, is used in the claimed process for the thermal drying process. The representation of the thermodynamic conditions for the desiccant within the nozzle and the state changes on the way to the suction port of the compressor can be represented in a wet air diagram.

As already mentioned above, according to the invention, after the wet finishing in the same machine unit, the strand-like fiber material is dried immediately afterwards. However, it is also quite conceivable that, after partial dewatering carried out in the manner described, the goods are passed into a separate dryer with several compartments to be shut off with the aid of the compressor connected to the other dyeing machine.

The drying process according to the present invention proceeds as follows: In order to bring the material subjected to a wet finishing to a desired residual moisture content - regardless of whether one has provided partial dewatering or predrying or full drying - the aggregate loaded with the moist textile material is compared to that Fleet circuit closed and the compressor is switched on. A predetermined overpressure then arises in the overall system. The density, the flow velocity and the kinetic energy of the steam-air mixture increase. The latter is then able to tear the water adhering to the textile material in the form of very fine droplets.

The moisture transferred into the gas space and taken up by the gas stream is then removed from the circulating line of goods in this way and the moist air mixture formed on this occasion is removed from the treatment zone at the end of the common transport route and measures for drying are subjected. The recooling required to separate the moisture from the oversaturated exhaust air takes place in an air cooler to the recooling temperature specified by the respective drying process. The moisture which condenses when the temperature falls below the dew point coalesces in the downstream water separator, whereupon the gaseous medium thus dried is again fed to the circuit, compressed and heated and brought to action again on the moist strand material.

It is currently common in the textile industry not to completely dewater a product that is refined, for example, after dyeing. A certain amount of residual moisture is often even desirable. According to the method, it is now readily possible to dry in the nozzle dyeing unit in this way to control that the goods are conditioned at the same time, which applies to all types of fabric. Such a project can be realized by dewatering the fabric strand within the closed dyeing jet to a state of equilibrium of the material moisture, which corresponds to the conditioning moisture after removal from the system and cooling of the textile material, or by lowering the fabric strand within the closed dyeing jet Conditioned moisture of the same dewatered and then carries out a conditioning of the textile material by increasing the relative humidity of the drying air. The last-mentioned principle of humidification by means of conditioned air of a certain temperature and a certain moisture content is used on a similar basis in the case of DE-OS 20 52 440 in the conditioning of yarn packages from hygroscopic fiber material to compensate for the different degrees of moisture between the inner and outer layers of the coil winding Made use of.

A device suitable for carrying out the claimed method, to which the present invention also relates, is characterized in that a jet dyeing machine of a conventional type suitable for the hydraulic drive of endless textile strands by means of a treatment liquid, with a separate circuit for a goods feed, if necessary supporting or solely continuing gas flow is connected, in which - arranged in the order given - means for compressing the gaseous medium and for subsequent heating thereof, a contact path for the drive gas effective from a built-in nozzle arrangement for the transport of goods together with the circulating textile material, means for Recooling the resulting gas stream, including the removal of moisture from it, and means for separating the resulting condensate.

• A = Jet-Färbemaschine (Druckbehälter) aus Antriebsteil (Haspel), Transportdüse und Warenspeicherraum samt Abfluß (nicht mit Ziffern versehen)
• B = Zirkulationssystem für die Flotte, bestehend aus Umwälzpumpe, Wärmeaustauscher für Heizung und Kühlung mit nachgeordneter Drosselvorrichtung zur Regulierung der Flottenströmung (nicht mit Ziffern versehen)
• C = Ansatz- sowie Vorratsgefäß für Behandlungsflüssigkeiten mit nachgeordneter Dosierpumpe und Absperrventil (nicht mit Ziffern versehen)
• W = Behandlungsgut/Warenstrang
• 1 = Gebläse (Verdichter)
• 2 = Lufterhitzer
• 3 = Luftkühler (Kondensator)
• 4 = Abscheider für Feuchtigkeit aus der Umluft
• 5 = Absperrklappen
• 6 = Druckluftanschluß (Gasanschluß)
• 7 = Dampfanschluß
• 8 = Injektionsdüse für Wasser (evtl. Zumischung von Ausrüstungsprodukten)
• 9 = Feuchtekondensatablaß

An exemplary embodiment of a jet dyeing system used according to the invention is shown schematically in cross section in the drawing of FIG. 1 given below. The reference symbols used are identical to the numbers used for this purpose in the text and have the following meaning:

• A = Jet dyeing machine (pressure vessel) consisting of drive part (reel), transport nozzle and goods storage space including drain (not numbered)
• B = circulation system for the fleet, consisting of a circulation pump, heat exchanger for heating and cooling with a downstream throttle device for regulating the fleet flow (not numbered)
• C = preparation and storage vessel for treatment liquids with downstream metering pump and shut-off valve (not numbered)
• W = material to be treated / strand of goods
• 1 = blower (compressor)
• 2 = air heater
• 3 = air cooler (condenser)
• 4 = separator for moisture from the circulating air
• 5 = butterfly valves
• 6 = compressed air connection (gas connection)
• 7 = steam connection
• 8 = injection nozzle for water (possibly adding equipment products)
• 9 = moisture condensate drain

In this Fig. 1, the parts of the jet dyeing machine designated by letters A, B and C correspond in large parts to the prototype of such a device as this in the U.S. Patent 3,949,575 is described in detail.

The principle of operation of the claimed device can be explained as follows:
Following a wet finishing under the action of the circulation system B (with the circulation pump started and the shut-off valves 5 closed) with the treatment liquor fed from the storage container _C (containing the finishing agent) and after the goods storage space has been emptied of ^* drying or partial dewatering of the in the jet dyeing machine A in unchanged loading form as previously circulating product line W, the two butterfly valves 5 for the circulation of the gaseous drying agent are opened and the blower 1 is switched on. By introducing compressed air from a compressed air source, not shown, via the connection 6 for the first filling of the interconnected via a line (not numbered) from the one now serving as a drying vessel. Dyeing jet A, the air cooler 3, the water separator 4, the blower 1 and the air heater 2 existing orbit for the cycle of the gaseous desiccant creates an intended overpressure of, for example, approx. 2.5 bar in the overall system. The density of the gas volume thus increases, as a result of which the total pressure difference prevailing at the blower 1 increases and thus also the air weight flowing per second. The flow velocity also increases and the kinetic energy of the steam-air mixture increases accordingly. The surface moisture is detached from the textile material and, as it were, eliminated as a mist in the form of very fine water droplets from the gas flow acting as a vehicle. The intensity of this drying section corresponds to that of mechanical dewatering, as can be achieved in a centrifuge, but the goods are dried without wrinkling. ^k mostly extracted liquid medium become In order to also provide thermal energy for the drying of the moving strand W and in this way to support the swirling effect of the air flow to remove moisture, the gaseous drying agent compressed in the blower 1 to the back pressure caused by the amount of air in the downstream air heater 2 is set to a predetermined value Drying temperature warmed up and so gradually brought the moisture under the influence of the heat contained in the drying air to evaporate. According to the method, a heated steam-air mixture can preferably be used instead of air as the operating gas for the drying agent circuit by supplying steam via the connection 7.

At the end of the common transport path of the desiccant with the circulating strand W, the steam-air mixture, which is laden with moisture and emerges from the drying vessel A (dyeing jet), is cooled to the intended recooling temperature during passage through an air cooler 3, whereupon the separator 4 connects the downstream Supersaturated water content contained in the exhaust air separates out under condensation and is removed through the outlet 9. The almost water-free drying air leaving the water separator 4 or the dry-saturated steam-air mixture is then sucked in and compressed again with the aid of the blower 1 and, after subsequent warming up in the air heater 2, again in the drying vessel A to act on the goods W. - and passed through.

For the conditioning of the textile goods, the specified state values of the moist air mixture in the machine system are controlled and the injection nozzle 8 atomizes a specified amount of water per unit of time for a certain period of time in the circuit. This will expediently happen when the desired degree of drying has been reached.

• Innerhalb der Transportdüse der Jet-Färbemaschine trifft das in Umluft befindliche

To illustrate the thermodynamic conditions of the drying method according to the invention, a simplified graphical representation of the drying process for a specific drying section is shown in FIG. 2 in an H, x diagram of moist air with flat, rectangular coordinates:

• Inside the transport nozzle of the jet dyeing machine, the one in the circulating air hits

Steam-air mixture with the condition L1 on the damp goods. For the entry in the coordinate network, the state L1 can be characterized by the values heat content H, steam or moisture content x and temperature. The drying air then flows in contact with the goods to be dried from the nozzle via a common transport path and the goods store to the exit point from the drying vessel. The state L1 of the drying air changes approximately on a straight line, the direction of which can be plotted over the edge scale Δ H / 4 x, taking into account the good temperature for the steady state. The condition L2 of the drying air reflects the conditions at the outlet of the goods store, depending on the drying process. Due to the cooling of the drying air to state L2 which occurs when the strand is acted on, the moisture in the drying air is simultaneously taken up together with a corresponding heat transfer to the textile goods, on the occasion of the dewatering of the goods brought about during this treatment phase. In the recooling of the drying air, which is now loaded with moisture, in the air cooler 3 after separation of the strand material accompanied up to that point, no change in the moisture content of the outflowing air is registered until the dew point line ψ = 1 (saturation line) is reached in state point L3.

Only in the course of the further reduction in the recooling temperature does the release of the supersaturated water content contained in the gaseous drying agent then occur, which is shown as a change in the direction of the drying process in the sense of a shift of the condition point for the drying air to the left along the saturation line to state L4. This then leads to a reduction in the moisture content of the drying air under condensation by the amount x ₃ -x ₄ kg of moisture per kg of dry air. This moisture content is separated from the drying air in the separator 4 and discharged from the machine. The state L4 of the drying air characterizes its condition at the intake port of the blower 1, the drying air being heated to the state L5 by the amount of the compression work in the course of the subsequent compression with the moisture content unchanged. The subsequent section from state L5 to state L1 then provides information about the amount of heat given off by the supply of heat from the air heater 2 to the drying air. When the steam-air mixture is heated from the saturated state in point L4 to the initial state of the circuit in point L1, the moisture content x = remains constant, so that there is a vertical course of the change in state.

The state L2 in the diagram explained above generally corresponds to the result of the interaction of the influences of two amounts of moist air, namely formed from the amount that flows into the nozzle from the compressor and the amount that is sucked into the nozzle with the goods.

Claims (5)

1. A process for the partial or complete drying of batches of goods made of textile fabrics or knitted fabrics discontinuously circulating in endless form in jet piece dyeing systems following a wet treatment operation for textile finishing according to the pull-out technique, whereby the feed for the transport of the fiber material within the self-contained system is transferred operates the actuation of the nozzle system, characterized in that immediately after the wet refinement and after the treatment liquid has been drained off from this previous processing step in the course of the one now taken over and maintained by a gas stream. Locomotion of the wet-finished, moist fabric strand, evaporation drainage of the same to a certain residual moisture content when it meets, and subsequent flow around with the drive gas which is circulated to a predetermined excess pressure in the same apparatus arrangement via an associated separate circuit, and subsequent cooling of the after absorption of moisture due to the previous measure gas mixture resulting from exhaust gas from a supersaturated to a dry-saturated state with simultaneous recondensation of the moisture removed from the textile material and separation of the same from the cycle of the gaseous drying agent. 2. The method according to claim 1, characterized in that a compressed vapor-air mixture is used as the drying agent, which contributes necessary heat energy for evaporation of the moisture. 3. The method according to claim 1 or 2, characterized in that the fabric strand within the closed dyeing jet is dewatered to an equilibrium state of the material moisture, which corresponds to the conditioning moisture after removal from the system and cooling of the textile material. 4. The method according to claim 1 or 2, characterized in that the fabric strand within the closed dyeing jet dewatered to below the conditioning moisture and thereafter carrying out a conditioning of the textile material by increasing the relative humidity of the drying air. 5. A device for performing the method according to claims 1 to 4, characterized in that a suitable for hydraulic drive of textile fabric strands in endless form by means of a treatment liquid jet dyeing machine of a conventional design with a separate circuit for a product feed, if necessary, supporting or solely continuing gas stream is connected, in which - arranged in the specified order - means for compressing the gaseous medium and for subsequent heating thereof, a contact path for the drive gas effective from an installed nozzle arrangement for the transport of goods together with the circulating textile material, means for recooling the resulting gas stream including the removal of moisture from this, and means for separating the condensate obtained here are present.

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