EP1660709A1 - Method for compressive shrinking and rubber blanket shrinking system - Google Patents

Abstract

This plant is used to treat textile webs (9) which do not fully cover the width of the cloth belt (3) and of the cylinder (1). This leaves inactive regions of the belt at its edges, which may be subjected to greater heating. Such regions are separately and more strongly cooled than the active regions (27) of coverage, after lifting-off the main cylinder. An independent claim is included for the corresponding pre-shrinkage plant for textiles.

Description

"Compressive Shrinking Process and Blanket Shrinking System"

Description:

The invention relates to a method for compressively shrinking a textile fabric with the aid of a compressive or rubber blanket shrinking system, in which a mechanically compressed web is fixed between an endless rubber blanket and the outer surface of a heated master cylinder or heating cylinder, and in which each of the master cylinder running area of the blanket is cooled. It also relates to a rubber blanket shrinking system in which a mechanically compressed web of material is to be fixed between an endless rubber blanket and the outer surface of a heated master cylinder and in which coolant is assigned to the region of the rubber blanket running from the master cylinder. The rubber blanket is also known as a rubber band or follower.

Blanket shrinking systems with so-called blanket calenders are described in DE-AS 10 72 220. The master cylinder of a crompressive shrinking cylinder is heated to about 130 ° Celsius when shrinking cotton goods in order to fix the mechanical compression of the respective fabric web. The heat supplied by the master cylinder not only heats up the fabric itself but also the rubber blanket pressing the fabric against the master cylinder. Since the width of the fabric fluctuates - at least from batch to batch - the rubber blanket will generally be wider than the treated fabric.

Due to the heat of the master cylinder, the rubber blanket is heated to such an extent that plasticizers present in the rubber blanket migrate to the outside (migrate). To slow down this effect, the rubber blanket in conventional shrinking systems is run off from the main cylinder and lifted the fixed Goods or fabric web are cooled with water over their entire width (see, for example, DE-AS 10 72 220 given above).

When running on the master cylinder, the (middle) areas covered by the fabric are heated less than the areas of the rubber blanket that are not touched by the fabric. The inventors have recognized that conventional cooling in the edge areas of the rubber blanket is not always sufficient, so that these edge areas can become brittle prematurely. In order to overcome this problem, the rubber blanket cannot be cooled more strongly, because if the rubber blanket is too cold, the mechanical compression of the fabric web is not properly fixed. In practice, it was therefore to be accepted that the rubber blanket would become brittle due to the heating of its surface and would have to be sanded down relatively often - about every two weeks during continuous operation. With each sanding, the originally 5-8 cm thick rubber blanket becomes thinner, and the thickness of the blanket reduces its shrinkage potential.

The invention has for its object to counter the premature wear of the areas of the blanket not covered by the fabric in the blanket calender of a compressive shrinking system, without the respective active areas of the blanket, that is, the blanket covered by the fabric during operation on the master cylinder - Areas to cool impermissibly. In other words, means are being sought to prevent premature embrittlement of the edge regions of the rubber blanket located outside the width of the web.

The solution according to the invention is specified for the method mentioned in the characterizing part of claim 1. It consists in particular in that, when used on a fabric web that does not completely cover the rubber blanket, the areas of the rubber blanket that are not covered by the fabric web on the master cylinder (that is, inactive with regard to shrinkage) are cooled more strongly after lifting off from the master cylinder than in the sense of the fixing success in the areas of the rubber blanket that are covered or active by the fabric. The solution exists for the rubber blanket shrinking machine specified at the beginning in that an additional cooling device which can be adapted to the width of the edge regions is assigned to the edge regions of the rubber blanket which are not touched by the fabric web. Some improvements and further refinements of the invention are specified in the subclaims.

According to the invention, the inactive areas of the rubber band that are not touched on the master cylinder by the fabric, in particular the areas on the longitudinal edges of the fabric, are to be cooled separately and to be cooled more than in the active areas of the rubber blanket with which the Fabric is pressed directly against the master cylinder, would be permissible. In the sense of the invention, "stronger cooling" means cooling to temperatures clearly, in the order of 5 to 20 ° Celsius, below the minimum temperature that is just permissible for the active area, in such a way that the amount of heat supplied to the auxiliary cooling device during the circulation of the rubber blanket at the additional cooling device (short The invention is based, inter alia, on the knowledge that a rubber blanket which has been heated up can only be cooled slowly again because of the poor thermal conductivity of rubber.

The invention is also intended to prevent the inactive areas from warming up from one cycle to the next. Penetration of the thermal energy applied to the master cylinder (and removed again at the cooling unit) into the interior of the rubber blanket should be avoided. The heat exchange between the master cylinder and blanket on the one hand and the blanket and cooling unit on the other should only be a thin one - e.g. of the order of magnitude 2 mm - concern the outer layer of the rubber blanket. This is also achieved by the relatively strong cooling of the edge areas according to the invention.

In the invention, the poor thermal conductivity of the rubber blanket is taken into account or exploited. The heat applied to the outer surface of such a cloth on the master cylinder penetrates only slowly into the depth of the cloth. The same applies to the effect of a blanket cooling, the cooling effect continues only slowly into the depth of the blanket. After a calculation it takes about two seconds for a layer around 1 cm below the heated rubber blanket surface to cool from 120 to 40 ° Celsius. Since rubber blankets run at a production speed in the order of 50 m / min (0.833 m / s), approximately 1.5 m of the rubber blanket would be required for cooling. Such a cooling length is not available in a compressive shrinking system. Without application of the invention, the heat applied to the master cylinder penetrates deeper in the peripheral areas from one circulation to the next, and the remaining temperature of the inactive peripheral areas rises to an equilibrium value which is unfavorable for the life of the rubber.

The invention addresses this problem in that the inactive edge areas are cooled so intensively from the start (essentially from the first circulation) that the amount of heat previously applied in the same circulation is practically completely removed again. This means that the thermal energy has no opportunity to penetrate deeply into the material of the rubber blanket - at least not with an impermissible temperature range - and accordingly only a relatively thin outer layer is alternately heated and cooled. If this heated or cooled down outer layer is, for example, 2 mm thick, it can (in the above-mentioned calculation example) be cooled down from 120 ° to 40 ° Celsius in the order of 0.3 seconds; at the above-mentioned speed of 50 m / min only about 25 cm are then required for cooling; Cooling paths of this length can, however, be easily mastered in conventional blanket shrinking systems.

The cooling of the inactive marginal areas of the rubber blanket according to the invention is preferably started immediately after the machine is started. Preferably, the cooling capacity per cycle - in the inactive peripheral areas - should be at least approximately equal to the heating capacity per cycle.

According to a further invention, the above-defined edge regions of the rubber blanket are each assigned an (additional) cooling device which can be adapted to the respective width of the edge regions. For example, air or water jets from nozzles to the inactive marginal areas of the rubber blanket. In order to generate the jets, pivotable nozzle bars, which carry the nozzles in question, can be provided. The width of the edge regions to be cooled, which is dependent on the width of the fabric web being treated, can be controlled by a sensor sensing the respective fabric web edge. Flat jet spray nozzles can be adapted particularly well to the respectively measured width of the (inactive) edge area to be cooled. Flat jet spray nozzles, the spray area of which is elongated almost like a line on the treated surface, can be switched in stages depending on the edge width to be cooled. They also allow - inter alia by rotating the spray area (about an axis essentially perpendicular to the blanket) - a continuous adjustment to the width of the edge strips to be cooled if the flat jet and thus its spray area are rotated according to the edge width or the jet spacing is varied.

As an alternative to a single swiveling nozzle bar, a plurality of stationary nozzle bars can also be provided to adapt to the width. The individual nozzle bar can be assigned to a particular overall width of the respective edge area and can be controlled separately, for example by a valve. The nozzle bars can be equipped with flat jet nozzles. When using these nozzles, it is possible to align the spray area of the flat jet with a predetermined angle against the direction of travel of the rubber blanket. The number of stationary nozzle bars required depends on the maximum size of the inactive area of the rubber blanket to be sprayed (to be cooled), that is to say the ratio of the minimum web width to the rubber blanket width.

The aforementioned spray angle, with which the spray area of the flat jet is inclined against the edge of the rubber blanket, should be set separately for each nozzle bar, that is to say with a different orientation. In a preferred exemplary embodiment, the angle at which the spray region of the flat jet nozzles is inclined against the edge of the rubber blanket is in the case of a first nozzle bar which is assigned to an inactive edge region of the rubber blanket, for example 100 mm wide. should be made relatively small. On a second nozzle bar provided towards the center of the rubber blanket, the nozzles of which are intended to cover a wider, for example 200 mm wide edge area, the angle is chosen larger, namely made so large that the line-like, straight spray area (obliquely) extends from one longitudinal edge to the other of the edge area extends. In order to obtain the same spraying strength per unit area in the longitudinal direction as with the first nozzle bar, two (equally directed) flat jet nozzles can be provided on the second bar. Accordingly, both the angle of the flat jet (measured against the edge of the cloth) and the number of nozzles can be selected to be increasingly larger on each further, internal nozzle bar. If necessary, the same spray distance and the same intensity are achieved for each spray area.

The maximum edge width to be cooled in this way is predetermined by the length of the flat jet spray area. The length can be adjusted to the edge width by changing the distance between the nozzle and the rubber blanket. However, if a particularly narrow web of material is treated on a particularly wide machine (with a correspondingly wide rubber blanket) without damaging the rubber blanket, two or more nozzle bar groups of the aforementioned type can be provided at the edges of the rubber blanket at a distance of the length of a spray area.

As mentioned, water or air (or generally liquid or gases) can be provided as the coolant. The advantage of air cooling is better meterability, the advantage of water cooling is better effectiveness; however, the water sprayed onto the rubber blanket must be squeezed off before the cloth runs again into the area in which it is to perform the compressive shrinkage.

The coolants assigned to the inactive edge areas, for example nozzles, can have a separately controlled or separate coolant supply system in the manner of a countercurrent principle. If necessary, the same coolant, e.g. Fresh water, initially used for final cooling of the edge areas treated in each case. The return water generated there is pumped around and used to pre-cool the same edge area. This can also be done in three or more stages - the backwater flowing from a cooled area is used in each case to cool an even warmer edge area preceding in the direction of the rubber blanket.

Details of the invention are explained on the basis of the schematic representation of exemplary embodiments. Show it

Figure 1 is a schematic diagram in vertical longitudinal section through a rubber band shrinking system. 2 shows a plan view of the cooling area of the rubber blanket with movable cooling devices; and FIGS. 3 and 4 an embodiment with stationary cooling devices.

Fig. 1 shows a rubber band shrinking system in longitudinal section (perpendicular to the cylinder axes shown). The system consists in principle of a heated master cylinder 1, against the outer surface 2 of which an endless, stretched in the longitudinal direction rubber blanket 3 is pressed. This is passed over the so-called pressure roller 4 as well as over steering and deflection rollers 5, 6 in the running direction 7 shown. The corresponding direction of rotation 8 of the master cylinder 1 is also indicated by an arrow. The fabric web 9 to be shrunk runs in the indicated transport direction 10 via the pressure roller 4 into the so-called shrinking nip 11, where the mechanical shrinking takes place.

The mechanically caused shrinkage is fixed by the action of the heated master cylinder 1 with simultaneous pressing of the fabric web 9 by means of the rubber blanket 3 on the outer surface 2. The rubber blanket 3 has a predetermined initial thickness in order to achieve a significant shrinkage effect. If the cloth becomes brittle, it must be sanded down. In order to reduce the speed of embrittlement, the rubber blanket 3 is removed from the surface 2 cooled over its entire width with the help of a water shower 12. The cooling may only be carried out to the extent that the rubber blanket 3 is still so warm when it arrives again at the shrink nipple 11 that it can adequately support the fixing process on the outer surface 2 of the master cylinder. Before the rubber blanket 3 arrives at the pressure roller 4, the liquid applied with the water shower 12 must be pressed down to a defined residual moisture level, for example with the aid of a pair of squeeze rollers 13.

FIG. 2 describes exemplary embodiments of additional cooling devices according to the invention as a top view of the rubber blanket 3 and can be viewed as a view in the direction of arrow II in FIG. 1. Accordingly, 3 stumps of the rollers 5 and 6 as well as the (finished, shrunk and fixed) fabric web 9 running in the transport direction 10 can be seen in FIG. 2 behind the rubber blanket.

2 shows in the right half a (water) nozzle bar 16 which can be pivoted about a shaft 15 on a support 14. This has a plurality of nozzles 17 which follow one another in the longitudinal direction of the bar 16 as shown in the drawing and can have a liquid supply line 18 with a symbolically illustrated control valve 19. In addition, the bar has a swivel drive 20 which is to be designed, for example, in such a way that it can pivot the bar 16 in a predetermined manner about the axis 15 perpendicular to the plane of the drawing. The swivel drive can be controlled by means of a sensor 21, which (ultimately) determines by sensing the edge of the web of fabric how wide the individual edge regions 22 not covered by the web of fabric 9 on the rubber blanket 3 are. With the aid of the measurement results of the sensor 21, the swivel drive 20 can be controlled in such a way that the bar 16 with its nozzles 17 cools the two edge areas 22 with water.

In principle, similar to the water cooling bar 16 in the right half of FIG. 2, the air cooling bar 23 operates in the left half of FIG. 2. This bar can also be mounted on the carrier 14 with its axis 24 perpendicular to the plane of the drawing and one (not have) swivel drive, which can be controlled by a sensor - similar to sensor 21. The air cooling bar 23 should have a plurality of blowing or cooling nozzles 25, for example as shown, arranged side by side and one behind the other in the longitudinal direction of the bar 23. These cooling nozzles are directed onto the rubber blanket 3 by pivoting the bar 23 in such a way that they cool the respective edge area 22 as precisely as possible. For this purpose, the cooling beam 23 can be moved back and forth in the swivel direction 26 shown. In order to avoid undesired cooling of the area 27 of the rubber blanket 3 active on the master cylinder 1, a doctor blade 28 can be attached to the bar 23 (as well as to the bar 16). The active region 27 of the rubber blanket 3, that is the middle zone of the rubber blanket in the exemplary embodiment, delimits the rubber blanket region between the two edge regions 22, with the aid of which the fabric web 9 is pressed directly against the outer surface 2 of the master cylinder 1.

3 and 4 show the adaptation of the cooling area to the width of the fabric when using several stationary nozzle bars, the situation on the left edge of the blanket being described below. Spraying takes place in mirror image on the right edge of the rubber blanket. The same parts as in Figures 1 and 2 are given the same names.

From a collector 31 according to Fig. 3 through which the coolant, e.g. Cooling water or cooling air flows, several individual pipes 32 exit. The number of tubes 32 depends on the ratio of the minimum web width to the blanket width. Each of these tubes 32 is connected to a nozzle bar 33 a to e. A shut-off valve 34 is located between the respective pipe 32 and the associated nozzle bar 33.

According to FIG. 3, different numbers of flat jet nozzles are screwed into the nozzle bars 33a to e which follow one another in the direction 35 towards the center of the fabric web. It is assumed that each nozzle bar has four connection points for screwing in nozzles. A flat jet nozzle 37a is screwed into a middle position in the first beam 33a seen from the edge 36. In Two flat jet nozzles 37b are screwed into the second nozzle bar 33b seen from the edge 36. Three flat jet nozzles 37c are screwed into the third nozzle bar 33c seen from the edge. 3, the fourth nozzle bar 33d is also equipped with three flat jet nozzles 37d. The fifth nozzle bar 33e according to FIG. 3 has four flat jet nozzles 37e. In principle, however, other numbers of nozzles can also be provided in the various nozzle bars, but also linearly increasing numbers of nozzles (first bar one nozzle, second bar two nozzles, third bar three nozzles, fourth bar five nozzles, etc.) or other spatial distributions of the nozzles become.

In operation, the nozzles 33a to e produce long, narrow spray areas 38a to e according to FIGS. 3 and 4 on the rubber blanket 3. In the exemplary embodiment described, the nozzles of the different bars are oriented differently. According to FIG. 4, the spray angles w1 to w5 between the flat jet nozzle 37a to e or spray area 38a to e and the edge 36 of the rubber band are provided in the same manner in each individual bar, but vary from bar to bar. According to the drawing, the nozzle 37a is aligned or screwed into the first nozzle bar 33a such that the angle w1 between the edge 36 and the spray area 38a becomes relatively small. In this way, a minimally narrow edge region 22a can be cooled. When the second nozzle bar 33b is activated, the angle w2 between the spray area 38b and the edge 36 of the rubber blanket 3 becomes larger than the angle w1 and the edge area cooling accordingly. At the third nozzle bar 33c, the angle w3 becomes even larger, etc. When the nozzle bars 33e (and their nozzles 37e) are activated, an edge region 22b with maximum width can be cooled. The different number of flat jet nozzles 37 on each of the nozzle bars 33 and the different angles w ensure that the intensity of the spraying remains approximately the same even with a larger, inactive edge region 22 of the rubber blanket 3 to be sprayed.

The angles w1 to w5 mentioned can be selected, for example, in such a way that with the flat jet nozzle 37a an inactive rubber band strip of 100 mm on each the side can be sprayed and cooled. If the edge area is wider, for example 200 mm wide, the second nozzle bar 33b is switched on and the first nozzle bar 33a is switched off. If the edge areas are even wider, the next nozzle bars 33c to e are optionally activated. Within the scope of the invention, individual nozzle bars 33 can also be used at the same time for cooling the respective inactive edge region.

LIST OF REFERENCE NUMBERS

1 - master cylinder

2 = lateral surface

3 = rubber blanket

4 = pressure roller

5 = steering roller

6 = deflection roller

7 = running direction

8 = direction of rotation

9 = fabric panel

10 = direction of transport

11 = shrink nipple

12 = water shower

13 = pair of squeeze rollers

14 = carrier

15 = axis

16 = nozzle bar

17 = water jets

18 = water pipe

19 = valve

20 = rotary actuator

21 = sensor

22 = edge area

23 = nozzle bar

24 = axis

25 = nozzles

26 = swivel direction

27 = active area

28 = squeegee

31 = collector

32 = single tube

33: nozzle bar 34 = shut-off valve

35 = direction to the center of the fabric

36 = blanket edge

37 = flat jet nozzle

38 = spray area

w1-w5 = spray angle

Claims

claims:

1. A method for compressively shrinking a textile fabric (9) with the help of a rubber blanket shrinking system, in which the mechanically compressed fabric (9) is fixed between an endless rubber blanket (3) and the outer surface (2) of a heated master cylinder (1) and in which the area of the rubber blanket (3) running from the master cylinder (3) is cooled, characterized in that when applied to a fabric web (9) which does not completely cover the rubber blanket (3), the web web (9) on the master cylinder (1 ) previously uncovered, inactive areas (22) of the rubber blanket (3) after being lifted off the master cylinder (1) are cooled separately and more strongly than in the sense of the success of fixing in the active areas (27 ) of the rubber blanket (3) is permissible.

2. The method according to claim 1, characterized in that the inactive areas (22) cooled by an order of magnitude 5 to 20 ° Celsius more than the active area (27) of the rubber blanket (3) covered on the master cylinder (1) by the fabric web (9) become.

3. The method according to claim 1 or 2, characterized in that the amount of heat supplied to the inactive areas (22) in a rubber blanket circulation on the master cylinder (3) is substantially completely removed by the separate cooling of these areas during the same circulation.

4. The method according to at least one of claims 1 to 3, characterized in that the separate cooling of the inactive edge regions (22) takes place from the first circulation.

5. The method according to at least one of claims 1 to 4, characterized in that the inactive areas (22) are cooled in stages, preferably according to a type of countercurrent principle.

6. rubber blanket shrinking system in which a mechanically compressed web (9) between an endless rubber blanket (3) and the outer surface (2) of a heated master cylinder (1) is to be fixed and in which the area of the master cylinder (1) Rubber blanket (3) are assigned coolant (12), in particular for carrying out the method according to at least one of claims 1 to 5, characterized in that the inactive edge regions (22) of the master cylinder (1) which are not touched by the fabric web (7) Rubber blanket (3) - in the area after the expiration of the master cylinder (1) - one of the width of the edge areas (22) adaptable additional cooling device (16, 23) is assigned.

7. rubber blanket shrinking system according to claim 6, characterized in that the additional cooling device (16, 23) has means for spraying cooling water or air jets onto the edge regions (22).

8. blanket shrinking system according to claim 6 or 7, characterized in that pivotable cooling beams (16, 23) are provided as additional cooling device.

9. blanket shrinking system according to at least one of claims 6 to 8, characterized in that for controlling the width of the blanket area cooled by the respective additional cooling device (16, 23) at least one sensor (21) assigned to the web edge is provided.

10. blanket shrinking system according to at least one of claims 6 to 9, characterized in that for applying the coolant flat jet spray nozzles (37 a to e), in particular with a pivotable about the longitudinal axis of the jet, are provided.

11. rubber blanket shrinking system according to at least one of claims 6 to 10, characterized in that as an additional cooling device stationary Du- Senbalken are provided, wherein each edge region (22) is assigned at least one nozzle bar (33a to e).

12. rubber blanket shrinking system according to claim 11, characterized in that the nozzle bars (33 a to e) are arranged parallel to each other and in the direction (35) successive rubber blanket center.

13. blanket shrinking system according to claim 11 or 12, characterized in that the nozzle bars (33a to e) have a different number of flat jet nozzles (37a to e) with different spray angles (w1 to w5).

14. blanket shrinking system according to at least one of claims 11 to 13, characterized in that the nozzle bars (33a to e) from the edge (36) in the direction (35) center of the blanket (3) an increasing number of flat jet nozzles (37a to e ) and that the spray area (38a to e) of the nozzle bars generated by the nozzles are aligned flatter from the edge of the cloth towards the center.

15. blanket shrinking system according to at least one of claims 11 to 14, characterized in that each nozzle bar (33 a to e) via a shut-off valve (34) is connected to a collector (31) and that the nozzle bar with the same nozzle assembly - in pairs on the right and left - are to be driven.