CH288695A - Installation for the thermal finishing treatment of a textile material. - Google Patents

Description

  

  Installation for the thermal finishing treatment of a textile material. Certain fabrics consisting of fibers or containing fibers formed from certain synthetic materials, and in particular polyamides, are defective because they lack body, do not drape and have insufficient elasticity. In order to remedy these defects and improve the characteristics of these fibers, and in particular to make it possible to take advantage of their other advantageous properties, such as the strength and flexibility of the fibers, recourse is had to a fixing treatment. allowing to give them body.

   This treatment, as it has been practiced until now, comprises a fabric finishing operation (consisting of synthetic fibers based on polyamides or containing these fibers) and involves heating the fabric obtained by pressing the latter against a heated surface, maintaining a substantially constant pressure between the fabric and the heated surface, until the temperature of the fabric reaches a degree which is just below the melting point of the polyamide. Usually this requires heating the fabric to a temperature which ordinarily should not remain more than 5 to 25 ° C below the melting point of the polyamide and should generally be for a period of less than about 60 seconds. ron.

   The treatment conditions are delicate from the point of view of the relations which must exist between them, while remaining within certain relatively restricted limits, and of the relatively small exceedances of these limits, with regard to the heating period, the temperatures or treatment pressure, are such as to seriously affect the strength of the fibers.



  Various installations have already been proposed for making it possible to obtain industrially satisfactory fixing of fabrics composed of fibers based on polyamides. In one of the installations which have been suggested for this purpose, the fabric is passed between two heated surfaces, two heated rollers for example, between which the fabric is placed under a predetermined uniform pressure, over its entire width. In another installation, the fabric is passed along a fixed heated surface by means of an apron or belt. In yet another installation, the web of fabric is driven on a roller against which it is pushed by a heated sleeve or pad, substantially stationary.



  With the aim of making it possible to achieve an efficient and industrially profitable finishing of textile materials, in particular synthetic fibers, the present invention relates to an installation for the thermal finishing treatment of a textile material, characterized in that it comprises a enclosure delimiting a heating zone, means for continuously passing the textile material to be treated through this zone, in such a way that each element of material remains there for a period ranging from 1 to 10 seconds,

       A device for continuously directing at high speed a stream of heating gas having a predetermined temperature in order to ensure the thermal finishing of the textile material, this stream of gas being uniformly distributed over said material which is being processed in said heating zone.



  The appended drawing represents, by way of example, four embodiments of the installation forming the subject of the invention.



  Fig. 1 is a front view in cross section, partially cut away, of a first embodiment along the line I-I of FIG. 2.



  Fig. 2 is a side view, in cross section, of the installation shown in fi-. 1, following the line II = II of Belle-ci, showing in addition the front part as well as the cooling, driving and collecting devices: FIG. 3 is a side view of the installation which is shown in FIGS. 1 and 2, part of the side of the outer casing being torn off.



  Fig. 4 is a horizontal section along the line IV-IV of FIG. 2.



  Figs. 5 and 6 are, respectively, a side view and a plan showing details of a control device for rollers and helical parts which form part of the installation which is shown in the previous figures. o Fig. 7 is a top view showing details of part of the cooling and collecting roller control device shown in fig: 2.



  Fig. 8 is a side view, part in cross section and part broken away, of a second embodiment.



  Fig. 9 is a plan view corresponding to FIG. 8, part in cross section and part in cut away.



  Fig. 10. is an end view, in cross section, of the installation shown in FIG. 8, view along the X-X line thereof.



  Fig. 11 is a side view of a third embodiment, partly in cross section and partly broken away.



  Fig. 12 is a cross-sectional view of part of the installation shown in FIG. 11 following line XII-XII of the latter.



  Fig. 13 is a side view, partly in cross section and partly cut away, of a fourth embodiment.



  Fig. 14 is a front view corresponding to FIG. 13, partly in cross section and partly broken away.



  Fig. 15 is a perspective view of a gas chamber for rapid heating, as shown in FIGS. 13 and 14.



  By means of the installations shown, a fabric, capable of being fixed by heat, is passed in a substantially continuous fashion through a heating zone, and preferably at the rate of about 33 to <B > 132 </B> meter; per minute, continuously directing a stream of gas at a high speed, preferably of the order of more than about 120 meters, at a predetermined thermal fixation temperature of the fabric of the order of preferably 149 to 260 C (preferably around 205 to 246 C for a polyamide-based fabric),

   while this fabric travels through said heating zone for a length allowing each part of this fabric to be exposed to the action of the current of heating gas for a period of 1 to 10 seconds, and preferably subjecting said fabric cooling when it leaves the heating zone in question.



  In the installation shown in fig. 1 to 7; two rollers 1 and 2 are mounted in an outer casing 3. Another casing 4 is mounted inside the outer casing 3 and ends with curved arms forming conduits 5 and 5a. The internal surfaces 6 and 6a of the conduits 5 and 5a delimit a heating chamber situated around a part of the surfaces of the rollers 1 and 2.

    The internal surfaces 6 and 6a of the conduits 5 and 5a carry nozzles 7 and 7a which extend in the direction of the length of the surfaces of the rollers. The ends of the conduits and 5a are curved towards the rollers to end in nozzles 8 and 8a.

   Baffles 9, 9a and 10, 10a, respectively, are arranged inside the inner casing 4 to properly direct the heating gas to the various nozzles of the conduits 5 and 5a. On each of the conduits 5 and 5a are connected parts 11 and 11a, respectively, which extend in the form of conduits 12 and 12a, which terminate in flared openings 13 and 13a. The axes 14 and 14a of the rollers 1 and 2 pass, respectively, through the flared ends 13 and 13a and the adjacent parts of the conduits 12 and 12a. In this way,

   the flared ends 13 and 13a open out in the center of the rollers 1 and 2.



  A fan 15, mounted on a shaft 16 and receiving its control from a motor (not shown) via a chain 17, is installed inside the neck 1.8 of the casing 4. Hinged baffles 19 and 19a, placed inside the casing 4, make it possible to adjust the current of air passing through the connections formed by the baffles 9 and 9a, respectively.



  The anterior part 20 of the casing 3 carries a tray-shaped part 21 having a slot 22 and supported by rounded corners 23. Pairs of opposing scorers 24 and 24a, respectively, are provided in the rear part of the casing. the outer casing 3 and are supported by <B> U </B> supports 80, 80a bolted to angles or angle supports 81, 81a. These briilers are conventional gas burners, of the Venturi tube type, comprising extensions forming injectors 82, 82a, flared and perforated tubes 83,

       83a and outer tubes 84, 84a having air intake passages 85, 85a. Each pair of burners on the same side is supplied with combustible gas by means of a pipe 25 and a branch pipe 26 (fig. 3).



  A frame 28 is fixed to the front part 20 of the casing 3 and comprises transverse supports 30 and 30a, as well as lower supports 31 and 31a. Said frame supports a cooling roller 32, a shaft -33 of a roller 34 for driving the fabric, a shaft 35 for a fabric pick-up roller 36 and guide rollers 69, 70 and 72. A frame . auxiliary 30b, placed on one side of the main frame, carries toothed wheels 38, 39 and pinions 37, 40 and 40a, mounted on shafts 37a and 39a (Fig. 7).

   As shown in Figs. 2 and 7, the shaft 35 receives its command, by means of a chain 63, from the pin 37 mounted on the shaft 37a which, in turn; is actuated by the toothed wheel 38 meshing with the toothed wheel 39 mounted on the shaft 39a and receiving its control from the pinion 40, a chain 41 and a pinion 42 wedged on the shaft 14 of the roller 1. A second pinion 40a, mounted on the shaft 39a, behind the toothed wheel 39, actuates the cooling roller 32, via a chain 43 and a pinion 44.



  As will be seen by referring to FIGS. 2 and 3, the outer casing 3 comprises closed side walls 45, a rear wall 46, the front wall 20, a top 47 and a bottom 48. Under these conditions, the whole of the casing 3 is complete. Earth closed on all sides, with the exception of the slot 22 serving for the passage of a sheet of fabric inside the envelope and for the exit of this fabric. The top 47 of the outer casing 3 comprises an exhaust duct 27 of the fan. ,.



  The inner casing 4 has sides 49, thus defining a completely closed duct system for heating gas entering through the open neck 18 and expelled through the nozzles 7, 7a, 8 and 8a.



  The construction of the heating rollers is shown in fig. 1. As can be seen in this figure, the heating rollers, like the roll 1, carry, in their middle, a wall or baffle which divides the roll into two substantially equal halves. In each half, a number of cones 51a, 51b and 51c are mounted on the central shaft by means of flanged supports 52. Each of these cones has a central opening 53; the openings of successive cones gradually decreasing, the largest opening being at the outer end of the roll and the smallest near the center of said roll.

   The cones are spaced from the inner wall of the roll. Reinforcing spacers 54 are provided inside the rollers, at the location of the outer parts of the latter. The shafts of the rollers are mounted in bearings 55 and 55a ,, respectively. A series of spreader rollers 56, 57 and 58 (provided with helical grooves) are mounted inside the casing 3 and serve to guide, spread and (or) correctly place the web of soft tissue. vement.

   These rollers preferably rotate at a circumferential linear speed which is 5 to 201 / o greater than the circumferential linear speeds of rollers 1 and 2. A gear wheel 59 (fig. 1) is set on the shaft 14a and meshes with a wheel 60 actuated by a motor 61. The wheel 59 meshes with a wheel 62 mounted so as to be able to rotate on the shaft of the roller 58 (FIG. 5). The wheel 62 meshes with a wheel 64 wedged on the shaft 14.

   Pinions 65 and 66 (Figs. 5 and 6) are set on the shafts of rollers 56 and 57, respectively; a pinion 67 is fixed to the wheel 62, so as to be able to rotate freely with the latter on the shaft 58. A chain 68 establishes the communication between the pinions 65, 66 and 67 to enable their respective spreader or spreader rollers to turn. A pinion 87, wedged on the lower helical shaft 57, actuates the shaft 58 by means of a chain 68a and a pinion 88 wedged on the shaft 58.



  When the installation shown in fig. 1 to 7 works, a web of fabric on the feed roller 34 (fig. 2) is driven, by means of the guide rollers 69 and 70 and the roller 56, through the slot 22 towards the roller 1 passing under the lower surface 6 of the duct 5.

   The web of fabric, designated 71, passes from the upper roll 1 over the roll 58 and the lower roll 2, and from there under the nozzle-shaped surface 6a of the duct 5ta. The tablecloth passes from roll 2 around <B> of </B> roll 57 and comes out through slot 22 to come on. the roller. cooling 32 by means of guide rollers 72 and 73. The cooling roller is of the conventional hollow type and is provided with a cooling water circulation system (not shown). The fabric passes from the cooling roll, via the guide 74, to the pick-up roll 36 mounted on the shaft 35.

   The angles 23 extend over at least the width of the fabric web. They are adjustable in the vertical direction and are adjusted so that their rounded smooth parts come into tangent contact with the entering and exiting parts of the fabric web. A guide roller 23a serves to separate the entering and exiting parts of the web and is mounted so as to form with the angular part 23 a barrier which opposes the passage of excessive quantities of cold air into the heating zone. through slot 22. Fig. 2 shows the operation of the installation just after the priming of a new roll or piece of fabric. In this case, the roller 34 is almost full and the massaging roller 36 is relatively small.

   The situation as it occurs when the feed roller 34 reaches the end is shown in dotted lines. In this case, the feed roller will be relatively small and the pickup roller will be relatively large.



  The burners 24 and 24a heat the air or other heating medium in the jacket 3 and the fan 15 forces air into the duct system of the inner jacket. Part of the air passes directly through and exits through the central nozzles 7 and 7a, near the roller 58.

    Other air portions are deflected by the various baffles 9, 9a, 10, 10a and are forced back through the various nozzles 7, 7a which the surfaces 6 and 6a of the ducts 5 and 5a comprise. Still another part of the air, passed back into and through the duct system, is diverted into ducts 11 and 11a, respectively, to then pass through ducts 12 and 12a, respectively,

      and exit through the flared openings 13 and 13a. The air leaving these openings 13 and 13a will pass partly through the openings of the cones, to finally reach the inner plate 50 which deflects this air, which then exits along of the inner periphery of the roll. Because the dimensions of said openings decrease inwardly, part of the air is directed by each cone along the baffled surface of the cone and against the inner periphery of the roller.

    The air passes to the outside along the inner periphery of the roller to pass into the outer space 75 of the casing 3, from where it is drawn in by the fan 15. The nozzles 7 and 7a have shapes. and dimensions such that they can provide a relatively uniform forced heating gas flow across the width of the fabric, and the nozzles are preferably disposed radially of the circumference of the rollers, defining radial slots. which extend across the width of the web of fabric and are substantially parallel to the axis of. rotation of the respective rolls.

   The temperature of the air or other heating medium is thermostatically controlled to maintain a predetermined temperature or temperature range, the thermostatic element being shown schematically at 76 (Fig. 3).

    The air or other heating agent, expelled from the nozzles and directed against the moving web of fabric, is forced through the open sides 7 7 and 77a, and the open ends 78 and 78a (fig. 1 and 3) to be then led into the fan 15 which puts this air back into circulation through the installation. After a certain period of operation, an undesirable concentration of combustion gas and / or small humidity will occur in the heating gas which is recirculated through the installation.

   In this case, it is done. use of the exhaust duct -27 to remove by suction any desired quantity (the heating gas and preferably an amount not exceeding 30%. A suitable supply should be provided to replace the quantity of exhausted heating gas. Air is used as the heating agent, this can be replaced, within certain limits, by outside air leaking from different places, including slot 22.

   It is recommended, however, to have a separate air supply to replace exhausted heating air, "such as a 90 hinged panel door (Fig. 3). air (not shown) is preferably placed inside the intake duct, with a view to heating the intake air. 'There will thus have to be as little interference as possible with the temperature or the temperature range to be maintained in the air. 'installation.

   In many cases it is good and even advantageous to pre-adjust the exhaust to a certain degree and coordinate it with the make-up air intake to thereby automatically prevent unwanted moisture build-up and ( or) flue gas.



  The motor 61, used to drive the rollers, is preferably at variable speed. As a variant, any other conventional variable speed control system can be used. The speed at which the web of fabric travels through the envelope or heating zone must be carefully determined in advance depending on the fabric and the final finish that one wishes to give it and, for this purpose, it must conform to to the temperature or range of temperatures at which the heating is to be conducted. Thus, a given treatment may require heating the tissue to a given temperature, or within certain temperature limits, for a specified period of time.

   The speed of rotation of the rollers should then be adjusted so that the web of fabric can travel over the rollers and can enter and exit the envelope within a period of time ensuring that no part of the fabric is has remained in the heating zone longer than the predetermined period. For this reason, the use of a suitable cooling device, such as a cooling surface and / or a liquid cooling device, is important because 'it removes from the web of fabric any heat which could exert a continuous action and would thus tend to destroy the results obtained inside. the heating zone.



  Preferably, the fabric is passed through the heating zone, i.e. through the casing, at the rate of about 33 to 132 meters per minute. The temperature prevailing inside the heating zone is maintained, depending on the particular type of material treated, at a temperature or within predetermined temperature limits ranging between 149 and 260 ° C. and in particular, as regards fabrics. based on polyamides, between about 205 and 246 C, with the heating current being directed at a high speed over the web of fabric as it travels through the heating zone, preferably at a steady rate. 'at least 120 meters per minute.

   Satisfactory results have been obtained by directing the flow of heating gas towards the web of fabric at a rate of about 120 to 1200 meters at midnight. The heating zone has a length such that at the particular temperature predetermined for the thermal fixation of the treated material, the latter is subjected to heating for a period of 1 to 10 seconds. Instead of using two rollers, as in the installation described above, one can provide a single roll of support for the fabric web. This can, for example, be achieved by mounting an auxiliary guide roll 91 which allows the web of fabric to pass over a single roll.

   In this case, the fabric passes from the roller 56 on the roller 1 and leaves there through the opening 22, to pass directly to the guide roller 73, through the guide roller 91. This is shown in dotted lines at fig. 2.



  While the installation according to fig. 1 to 7 essentially comprises a fabric holder offering a support surface over the entire width of the web, - that shown in FIGS. 8-10 involves driving the fabric through the heating zone by a pair of endlessly moving spike frames which hold the edges of the fabric so as to maintain its shape.

   In this case, the sheet of fabric is in a way freely suspended between its edges which are held by said frames with <B> - </B> pins and there is no support surface on which the fabric is held. mine, as in the case of the installation which is shown in FIGS. 1 to 7.



  If reference is made in particular to FIGS. 8 to 10, it will be seen that 101 designates a casing in which wedge-shaped heating gas chambers 102 and 102a are mounted. Each of these chambers is provided with high speed heating gas nozzles 103 and 103a, of the same type as those which have been described heretofore, with reference to FIGS. 1 to 7. The heating zone is delimited by the space 104 existing between the heating chambers 102 and 102a.



  Heating gas conduits 105 and 105a are provided inside the casing 101 to supply heating gas to branch conduits 106 and 106a, arranged at the top of the chambers 102 and 102a, respectively, free of charge. communication with them.

    Pairs of thermostatically controlled gas burners 107 and 107a are mounted in a heating space 108 communicating with the heating gas conduits 105 and 105a. The heating ducts 105 and 105a are provided with baffles 108a, at their intersection with the ducts 106 and 106a, to balance the supply of gas to the heating chambers 102 and 102a. A fan 109, driven by a motor (not shown) is mounted in an opening provided in the partition 110 which separates the heating chamber 108 from the chamber 111 of the inner casing.



  A pair of cog wheels 112 is my tee; on a common shaft 113, inside the casing 101 and above the heating chamber 104. A corresponding pair of gears 112a is mounted, on a common shaft 113a, outside the heating chamber. casing 101, below the space defining the heating zone 104. Endless sprocket chains or belts 114 and 114a are driven by sprockets and are controlled as they travel through the heating chamber 104, by rigidly spaced pairs of guide rails 115.

   Two brushes 116 (only one of which is shown) are mounted so as to come into contact with the pins of the chain or belt, each of these brushes being adjacent to each of the pinions 112a of the lower pair. A web of fabric, unwinding from a feed roll 118, passes through the excess feeder shown schematically as a box 119. A fabric guide roll 120 is mounted at an adjacent point. to the upper pair of sprockets or sprockets 112.



  A partition wall 121, mounted inside the casing 101, defines a cooling compartment 122, in which are mounted cooling air chambers in the form of wedges 123 and 123a, supplied with cooling air. through transverse conduits 124 and 124a. The cooling chambers 123 and 123a are provided with high speed cooling air nozzles 125 and 125a, of shapes and dimensions similar to the heating gas nozzles 103 and 103a.

   Rooms 123 and 123a are. placed so as to define a cooling zone 126. Cooling gas connection ducts 127 and 127u are supplied with cooling gas, for example air, by a centrifugal fan 128 and pass the air from re cooling to the transverse ducts 124 and 124a and thence to the cooling chambers 123 and 123a. An exhaust device 129, powered by a motor, communicates with the cooling chamber 122.

         Guide rollers 130 and 131 cause the fabric to pass through the cooling zone 126, as it passes from the pick-up roller 120, through a slit 132, into the cooling part of the installation. A roller, 133, for taking up the fabric, is mounted so as to wind the fabric as it exits the cooling zone; guided by the guide roller 131. An exhaust pipe 134, mounted on top of the casing, serves to balance the system. heating gas mounted inside the casing 101 and to evacuate a certain quantity of heating gas, in the manner and for the purpose indicated with reference to the installation of fig. 1 to 7 ..



  When the installation shown in fig. 8 to 10 operates, the fabric passes through the device 119 and its two edges or edges are then driven into the pins of each of the endless chains 114 by means of the brushes 116.

   The web of fabric, held in shape and in position by the spiked chains, on each side of this web, and controlled by the rigid frame 115, travels through the heating zone 104 and is withdrawn from the warp to pass over. the guide roller 120 and, from there, through the slot 132, on the guide roller 130, through the cooling zone 126, to then exit the installation through the slot 126a and pass over the roller envirage. 133 via the guide roller 131. As the fabric travels through the heating zone 104, a rapid stream of heating gas directed at the fabric licks both sides of it as it passes.

   through the nozzles 103 and 103a of the heating gas chambers 102 and 102a. The drive of the pin chains 114 on the sprockets 112 and 112a is combined such that the chains move at. a speed of 33 to 132 meters per minute.

   Thermostatic controls (not shown) are provided to maintain the temperature of the heating gas stream within the limits of 205 to 245 C. The balance of the heating gas stream inside the installation and the force which is imparted to it by the fan 109 passing the current of heating gas through the various conduits to the nozzles 103 and 103a are calculated in such a way that the speed of the current of heating gas as it licks the sheet of moving fabric exceeds approximately 120 meters per minute, and is preferably between 120 and 1200 meters per minute.

   When the fabric leaves the heating zone to enter the cooling zone 126, high speed cooling air licks this fabric on both sides to cool it quickly and do so. move out of the hazardous temperature zone which could cause overheating or excessive fixation of the fabric.



  The length of the heating zone, as defined between the nozzle surfaces of the heating gas chambers, is calculated so that the articles passing through it are exposed to the predetermined heat-fixing temperature at their speed. of progress. particular, for a period of 1 to 10 seconds. It is appropriate, depending on the particular construction which. is used, to bring within the effective dimensions of the heating zone the entire stroke made by the articles from the point of entry into the part of the installation where the heating takes place to the point of 'entry into the cooling zone thereof.

   The total exposure of each part. Fabric at the predetermined temperature for heat setting is thus limited, so as not to exceed substantially 10 seconds.



  In the installation shown in fig. 11 and 12, a. casing 201 contains double wedge-shaped heating chambers 202 and 202a, provided with high-speed heating gas nozzles 203 and 203a, and defining, between their nozzle surfaces, a heating zone 204.

   A centrifugal fan 205, mounted on a shaft 206 and powered by a motor 207, supplies high speed heating gas through branch pipes 208 and 208a in communication with the heating air chambers 202 and 202a. Baffles for heating gas control, - 209 and 209a,

      are used to adjust the balance of the heating gas supplied to rooms 202 @ and 202a. Pairs of sprockets 210 and 210a are provided - qai carry pairs of endless spike chains 211 mounted on sprockets 210a - to serve to support the fabric through the heating zone 204. Two brushes 212 (one of which is only has been shown), each mounted at a point adjacent to the pair of gears 210, serve to press the edge of the fabric web in contact with the pins.

   A fabric pickup roller 213 is mounted adjacent to the pair of pins 210a and serves to guide the web of fabric 214 to a take-up roll 215. A roll 216 passes the fabric through a feeder 217. from where it passes over the spigot frame 211. A pair of gas burners 218 is mounted in the fan casing 219. Exhaust pipes 220 and 221 serve to balance the heating gas system inside. of the installation.

   A device for cooling the fabric layer 222 is provided at the collector end of the installation and comprises a casing 223, cooling gas chambers 224 and 224a, provided with gas cooling nozzles at the end of the installation. high speed 225 and 225a, and delivers cooling gas through conduits 226 and 226a, provided with fans 227 and 227a, respectively.



  The web of fabric passes from the feed roll 216 to the excess driver 217; then passes through the pairs of endless chains with pins 211 in the pins from which the edges of the fabric are pressed by the brushes 212. The web of fabric is dragged by the chains in question through a slot 220a, from the end entry of the envelope 201, through the heating zone 204, to exit through a slot <B> 227b, </B> at the pick-up end of the envelope 201. The web of fabric 214 is removed from the endless sprocket chains 211 by means of the pickup and guide roller 213, to then wrap around the winding roller 215.

    Said chains are actuated so as to move at a rate of 33 to 132 meters approximately per minute. The flow of heating gas is maintained at a temperature of about 205 to 246 C and is discharged through the heating ducts 208 and 208a into the heating gas chambers 202 and 202a by means of the centrifugal fan 205 .

    The rapid heating gas nozzles and the propulsive force of the centrifugal fan are adjusted so that the catalyst gas exits from the nozzles 203 and 203a so as to lick the faces of the moving web of fabric. The rate is about 120 to 1,200 meters per minute, the length of the area within which the fabric is subjected to heat setting temperatures being calculated so that the fabric can be trapped. pour, at its travel speed, in a time varying between 1 and 10 seconds.



  The excess driver 217, as well as the corresponding device 119 (Fig. 8) serve to drive the tissue in a loose state to avoid abnormal tension which would result from shrinkage or shrinkage during heat treatment.



  As the fabric moves through the cooling zone 223a, defined between the nozzle surfaces of the cooling gas chambers 224 and 224a, cooling gas, preferably at high speed, supplied by the propellant fans 227 and 227a, as well as the conduits 226 and 226a, is forced back through the nozzles 225 and 225a to come and lick the faces of the sheet of mobile fabric 214 and then escape at 222a.



  The installations which are shown, by way of example, in FIGS. 8 to 12, advantageously lend themselves to the heat treatment for finishing the layers of relatively loose fabric and in particular for knits. For the latter, it is essential that the heat setting be effected while the web of fabric is held rigidly under a uniform width, so as to avoid uneven shrinkage and formation of a web. with uneven waves.

    For the best results, it is advantageous not only to entrain a slightly excess amount of fabric before it passes through the heating zone, but also to adjust the distance between the supporting parts of each pair of chains. endless spikes to allow at least medium shrinkage in the width, during the heat treatment of the articles. Figs. 13 to 15 show an installation which is suitable for the heat treatment of prefabricated textile articles, such as, for example, ladies' hosiery. In these figures, 301 designates a casing with pro length 301a for a fan.

   The casing 301 has side, top and bottom closure plates 302. Wedge-shaped heating gas chambers 311 and 311a have high-speed heating gas nozzles 312 and 312a, respectively, and are disposed therein. of the casing 301 to define, between their faces with nozzles, the heating zone 310. A centrifugal fan 307 is mounted on a shaft 306- actuated by a pulley 305. The fan 307 is surrounded by a casing with open ends 330 to which are connected heating gas conduits 308 and 308a which lead, respectively, into the heating gas chambers 311 and 311a.

    Gas pipe connections supply the burners 303 and 303a. Multiple brackets 309 for hosiery are mounted on pins 318 attached to endless chains 319, which slide on a rigid rail 320 mounted on brackets 321. A cooling compartment 340 is provided at the discharge end of the hosiery. installation and carries a centrifugal fan 341 mounted in a casing 342 which is connected to conduits 343 and 343a leading to a pair of wedge-shaped cooling gas chambers 344.

   The system of fans and ducts said cooling compartment 340 is similar to that which supplies the current of heating gas. The cooling gas chambers 344 are constructed in a similar fashion to chambers 311 and 311a, except that they are shorter. A partition 345 separates the heating part from the part. system cooling. An exhaust fan 346, carried by the cooling chamber 340, communicates with the interior of the casing 34 "of the cooling compartment 340.

        In the processing of prefabricated textile articles, such as ladies' hosiery, with the aid of the plant which is shown in figs. 13-15, pre-fabricated pieces of fabric are placed over the multiple forms which continuously enter, pass through and exit the facility. Said shapes, concurrently with the chains which are connected to them, travel continuously through the zone 310.

   The chains 319 are arranged in the conventional form of an endless belt or belt (not shown), so that, after leaving the installation at the output end, they return to the input end. of the latter. One worker places the pre-fabricated pieces of fabric, such as hosiery, on the lasts at the inlet end of the facility, and another worker removes the heat-set fabric from the lasts as these shapes come out of the discharge end of the installation.

   Conventional members for controlling the chain (not shown) are arranged and adjusted so as to make the chain run through the installation at a speed of about 33 to 132 meters per minute. The length of the heating zone through which the articles pass is calculated such that, at a predetermined speed; items remain in the heating zone for a period of 1 to 10 seconds.

   The heating gas is continuously sucked into the interior of the centrifugal fan 307 which sends it to the conduits 308 and 308a from where it passes into the heating chambers 311 and 311a and leaves, at a high speed, by the nozzles 312 and 312a. The propulsive power of the fan is adjusted so that the heating gas comes to lick the fabric which travels on the forms through the heating zone at a speed of about 120 to 1200 meters at midnight.

   Said high speed heating gas, after licking the fabric, is deflected into the heating part of the casing 301 and from there back to the fan 307, passing through the heating zone. Gas burners 303 and 303a are thermostatically controlled, so as to maintain the temperature of the return heating gas to a degree which allows it to be delivered to the heating zone at a temperature of approximately 205 to 246. vs.



  After the articles pass through the heating zone 310, they pass through the cooling compartment 340. In the latter, the centrifugal fan 341 is in communication, through its open ends, with the outside air. Fresh air is continuously sucked inside the fan and expelled towards the periphery and, through the connection ducts 343 and 343a, into the pair of cooling gas chambers from which cooling air , at a relatively high velocity, is passed through the nozzles 350 over the articles placed on the forms as the forms travel through the cooling passage defined by the opposing nozzle surfaces.

   The cooling air then escapes through the exhaust fan 346.



  When use is made, for the treatment of prefabricated fabrics, of an installation such as that shown in FIGS. 13 to 15, there is an advantage, as will be seen in this example, in having the high-speed gas nozzles opening into the heating zone, and preferably also those which open into the cooling passage, so as to form an angle with the direction that the tissue being treated is following, and preferably at an angle of 45 with that direction.



  Although it is preferable to use air as a heating agent in the installations shown, it is possible and sometimes even advisable, depending on the conditions and particular circumstances which may arise, to use air. another mixture of gas, and preferably an inert gas, as a heating agent. This is particularly recommended in cases where special tints or shades tend to oxidize under the action. heat and where it is necessary to resort, to avoid the destruction of these nuances, to the use of a non-oxidizing heating agent.



  Although the installations shown have been described in their application to the fixing under the action of heat of fabrics or textile materials based on polyamides; they have proved to be equally suitable for fixing other fabrics or textile materials, and in particular for which it is customary to have recourse to a heat treatment, as when the result is desired. a special finish.

   Experience has shown that in many cases these facilities can make these finishing treatments more efficient and economical and less subject to operator control. that this was not possible with the known installations and that, in many cases also, the application of these installations to these special heat treatments made it possible, for the first time, to subject the articles to the particular heat treatment applied to high speeds.



  As an example of the utility of the installation according to the invention for the heat fixing of articles other than polyamides, mention may be made in particular of the heat treatment of acetates. In this case, a sheet of fabric consisting of acetate fibers or containing these fibers is passed through, for example in the installation which is shown in FIGS. 1 to 7, at speeds ranging between 33 and 132 meters per minute, the total exposure time being from 1 to 10 seconds and the temperature inside the heating zone varying between 149 and 1b2 C. In this way, a very advantageous polishing effect, similar to that of printed fabrics, was obtained.

   This is why, in order to ensure maximum flexibility for the installations shown, it is preferable that they be able to operate with a range of temperatures ranging, for example, from 149 to about 260 C.

 

Claims (1)

CLAIM: Installation for the thermal finishing treatment of a textile material, characterized in that it comprises a delimiting enclosure. a heating zone, means to pass from. in such a way that the textile material to be treated is continued through this zone, such that each element of material remains there for a period ranging from 1 to 10 seconds, a device for continuously directing at high speed a current of heating gas having a predetermined temperature in order to ensure the thermal finishing of the textile material, this gas stream being uniformly distributed over said material which is being treated in said heating zone. SUB-CLAIMS 1. Installation according to claim, characterized in that said device for directing a stream of gas is constructed so as to impart to said gas a speed of at least 120 meters per minute. 2. Installation according to claim and sub-claim 1, characterized in that said device for. directing a stream of gas is constructed in such a way that said stream is sent at a temperature ranging from 149 to 260 C. 3. Installation according to -claim and sub-claims 1 and 2, characterized in that said means for advancing the textile material through the heating zone are constructed so as to continuously advance a fabric to be treated. , hot, this fabric passing through said heating zone in the stretched state. 4. Installation according to claim and sub-claims 1 to 3, characterized in that the means for continuously advancing the textile material through the heating zone comprise an endless belt conveyor. 5. Installation according to claim and sub-claims 1 to 4, characterized in that the device for directing a current of heating gas at high speed is set up to send the gas to both sides of said tissue to be treated. 6. Installation according to claim and sub-claims 1 to 5; characterized in that said belt conveyor is established to operate at a linear speed of 33 to 132 meters per minute. 7. Installation according to claim, characterized in that it comprises a cooling zone located and constructed in such a way that the textile material passes through it after having passed through said heating zone. at. Installation according to claim, characterized in that the means for continuously passing the textile material through the heating chamber comprise a conveyor provided with profiled supports for articles of textile material capable of being heat treated.