DE2500637A1 - Strip material contactless support system - has gas supporting current striking strip at right angles - Google Patents

Abstract

The strip is supported and guided on a gas cushion, delivered via a supply passage into a trough. The entire gas quantity for a section length strikes the strip (10) at right angles, emerging from a passage (18) running for the full section length, or from a port of relatively short length. The angle between the gas cushion trough sidewalls (16) ad the horizontal can be between 10 and 30 deg., typically 25 deg., and where the passage joins the sidewalls the surface can be of hyperbola section. The hyperbola can be merge into a straight wall section at approximately 15 deg. to the horizontal.

Description

Device for the contact-free carrying of webs of material. The invention relates to a device for the contact-free carrying and guiding of webs of material on a gas olester that is created by supplying a gas from a supply duct is maintained in a gutter.

Such devices are used for the levitation of webs and Semi-finished products, in particular sheet metal strips, are used, which is a heat treatment and / or are to undergo a surface treatment.

For the contact-free carrying of webs of material are essentially two procedures became known. Either the one required for wearing Force generated by gas jets deflected on the material web or by a gas cushion, that builds up under the web.

A particular advantage of the gas blasting process is the high convective heat transfer from the gas flow to the one to be treated Train. However, this method is sufficient to produce a Force a great dynamic pressure in the rays required that contributes high temperatures because of the low gas density and because of the strength limits of the available fans not or only with considerable effort can be achieved. Another disadvantage of this method is that the gas jets Can cause markings on the material web.

These disadvantages of the method of carrying with the help of gas jets become avoided in the method based on the formation of a gas cushion in a gutter are based. The pressure required to carry the material web on the gas cushion is namely much lower than the total pressure in the gas jets.

Furthermore, because of the uniform speed distribution in no more markings are made on the gas cushion. The essential flat part the previously known gas cushion support systems can be seen in the fact that with them achievable heat transfer performance is only about 1/10 of the value that is can be achieved with gas jet support systems without special Afwand.

In order to stabilize the wearing behavior, is in a known method (DT-AS 1 205 291) the one supplied to the gas cushion Gas flow at entry diverted into the gas cushion channel so that it is tangential to the material web on the lower Limitation of the gas cushion channel laterally, i.e. towards the edges of the material web. However, this results in very large differences in the relative speed between Web and the treatment gas across the width of the web, as in one A high relative speed prevails while in the very narrow edge zone wide middle web area is only extremely small. This leads to an over the web width is very uneven heat transfer and therefore too large Temperature differences. In particular, edge overheating can be observed with this method do not rule out with certainty.

Another disadvantage of this known method is the high pressure loss, which is caused by the double shock loss, since the gas flow at the exit into the channel downstream of the deflection device - and when exiting the gap between Channel and web is deflected. Therefore, in this method of wearing the Material web in the supply channel a pressure for the gas cushion required that a Is a multiple of the weight per unit area to be held. The following numerical values are used specified: For a 1 mm thick aluminum strip, which corresponds to a weight per unit area of 2.8 kp /, a static pressure of 23 km / is required in the supply duct for the gas cushion. Because of this supply pressure for the gas cushion in comparison to the weight per unit area of the belt to be worn is very high, this gas cushion system is very high Temperatures, e.g. B. not suitable above 9000C, as for operation in industrial furnaces no fans are available that provide the required temperature at this temperature deliver high pressure.

The invention is therefore based on the object of a device of the specified type to create the disadvantages of the known devices does not have and himself especially at high temperatures can be used.

This object is achieved in that the entire Amount of gas for a section length from an opening with a compared to the section length short length or from the supply duct that extends over the entire length of the section perpendicular to the web to be carried.

This configuration of the gas supply changes the gas speed on the underside of the web only insignificantly, so that over the entire width of the goods an almost constant convective heat transfer and therefore a uniform one Temperature distribution is achieved.

Becomes the angle between the flat side walls of the gas cushion channel and the horizontal is selected to be between 100 and 300 and in particular 25 °, it is in the gas cushion over the entire width of the material web a constant static pressure. The pressure distribution can be made easier with the help Relationship of the stronology theory can be estimated theoretically.

Another advantage of the device according to the invention is the high Tipping stability. If the material web moves out of its horizontal rest position due to a moment deflected, the static pressure under the web in the edge area increases the lowered side. As a result, a restoring torque is generated and reliably avoided, that the edge of the web of material is in contact with the side wall of the gas cushion channel comes.

Finally, this configuration of the gas cushion channel is the Treatment gas flow, which is required to carry the material web, is very low held. For example, a test section two meters long for a web basis weight of approx. 9.2 kp / m2 for a perfect wearing the material web has sufficient static Pressure in the gas cushion of approx. 10 kp / m2 for the angle of inclination of the side walls of 150 a gas volume flow of only 0.24 m3 / sec. measured.

This already very low value can still be reduced to 0.206 m3 / sec.

decrease when the transition area from the supply channel to the Side walls of the gas cushion channel has liyperbelform, with the hyperbola to the top Edge of the side: ends in a straight line with an angle of inclination of about 15 ° to the IXoriontalen passes over. This configuration also changes the device the floating height of the web to be carried with a variation of the web width only very little. This is particularly important with regard to the small outflow losses Gas from the gas cushion channel at the head ends of the channel, i.e. at the channel cross-sections, at which the web of material enters or exits the channel is important.

These leakage losses can be caused by gas jet belts, which act like a gas lock can be almost completely avoided if the free cross-section is sufficiently small.

Another advantage of the device according to the invention is in the high attenuation of transverse vibrations of the web, in particular with the hyperbolic shape of the side walls of the gas cushion channel is achieved. For example became hyperbolic with a transverse deflection of 10% (6) of the web width Side walls measured a damping factor D g 0.3 (0.55).

The heat transfer from the treatment gas to the web can be achieved still increase by the fact that the gas emerging from the gas cushion flows through suitable formed side walls are so unguided that the top of the web of is applied to the gas flows.

After a further solution of the given problem flows at least part of the gas through slot nozzles or hole nozzles or a combination of hole and slot nozzles, which are inclined towards the center of the web, into the gas cushion channel a. As a result, heat emitters can be inserted into the guide grains or attach on its top. Will continue. so across the width of the web very smoothly he reached temperature curve.

To avoid edge overheating on very sensitive webs, can also use the side walls of the gas cushion channel in the area of the belt edges be formed like a lamella. The permeability achieved by these slats the wall surface can also by other surface designs, for example Perforation, can be achieved.

As a result, the treatment gas flow can be overspeed Avoid near the edges of the web.

The invention is illustrated below with the aid of exemplary embodiments Explained in more detail with reference to the accompanying schematic drawings.

They show: FIG. 1 a section through a device according to a Embodiment of the invention; Fig. 2 measured speed profiles in the cross section between the underside of the web and the side wall of the gas cushion channel; Fig. 3 shows a diagram of the measured and calculated pressure distribution over the width of the web bi horizontal web layer; 4 shows the pressure distribution during deflection the web from its horizontal Rest position through a moment; 5 shows a section through a further embodiment of one according to the invention Contraption; Fig. A section through an embodiment in which the top the material web is acted upon by the gas streams - and the streamlined arrows to scale were drawn in after a current consumption.

7 shows a section through a further embodiment of the invention Contraption; and FIG. 8 shows a section through a further embodiment of such a device Contraption.

In Fig. 1, a web 10 is shown, which on a gas cushion 12, which is formed in a channel 14. The channel 14 has flat Side walls 16, at their lowest points at the top of a supply channel 18 ends. The angle between the side walls and the horizontal is in the range between 10 and 300. An angle of 250 has proven to be particularly useful.

A system using the device according to the invention consists in generally from several sections. This hits all of the gas, for example has been brought to a certain temperature to carry out a heat treatment is, for a section length from a short opening compared to the section length or vertically from the supply channel 18 extending over the entire length of the section onto the web 10 to be worn.

The treatment gas thus flows in from the supply channel 18 above, butts against the web 10 and then flows with only slightly changing Speed along the underside of the web 10. At the edge gaps between the side walls 16 of the gas cushion channel 14 and the edges of the web 10 occurs the treatment from the formed between the side walls 16 and the web 10 Gas cushion off.

In Fig. 2 are measured velocity profiles in the cross section between the underside of the web 10 and the side walls 16 of the gas cushion channel 14 shown. It can be seen that the speed is at the bottom the web 10 changes only insignificantly.

Fig. 3 shows the measured and the calculated pressure distribution over the web width with a horizontal web position.

Only in an edge zone with a width of only about 2 ff The static pressure on the underside of the web is less than the width of the web as 90 ffi of the static pressure in the middle area of the web.

In Fig. 4 the effect of a moment is shown by which the Web 10 is deflected from its horizontal rest position. This increases the static pressure under the web in the edge area of the lowered side, see above that a restoring torque is generated and reliably avoided that the edges of the web 10 touch the side walls 16 of the gas cushion channel 14.

In the embodiment of the invention shown in FIG The device has at least the transition area between the upper edge of the supply channel 18 and the lower parts of the side walls 16 have a hyperbolic cross-section, the hyperbola merging into a straight line 20 in the upper region of the side walls 16. The angle of inclination of the straight line with the horizontal is 15 °.

Should a treatment be carried out, in particular a heat treatment, the surface of the goods can also be acted upon by the gas streams, so the gas flows emerging from the gas cushion 12 in the gaps 11 can pass through suitably designed side walls 22 (see Fig. 6) are deflected so that on the top of the web 10 directed gas streams 24 arise. ri3- 6 zciFt also the vtromlinien in such an arrangement; it can be seen that that Treatment gas from the supply channel 18 into the channel 14 and from there out the Gaps between the web 10 and the side walls 16 flows out. The exiting The gas flow is undirected at the side walls 22 and hits the top from above the web 10, from where it emerges vertically upwards from the device.

In Fig. 7 an embodiment of the present invention is shown, in which at least part of the gas is divided into several streams 26. Included a gas flow emerges from the supply channel 18 and is guided by a guide body 28 divided into two substreams 26. These substreams are passed through channels 30 between the gas cushion channel 32 and the guide body 28 and occur in the manner into the gas cushion 34 that they are inclined towards the rotte of the web 10. in the Guide body 28 or heat radiators 36 are attached to its upper side.

The partial gas flows 26 can be fed to the gas cushion 34 through slot nozzles, fed through hole nozzles or through a combination of slot and hole nozzles will.

In Fig. 8 is an embodiment of the device according to the invention shown, in which the side walls 38 in the region of the edges of the web 10 is permeable are trained. For this purpose, lanelles 40 are provided in the embodiment shown. The permeability of the wall surface can, however, also be achieved through other surface designs, z. B. perforation.

In all of the illustrated embodiments, above and below the Web 10 heat radiators are arranged. Furthermore, in the inlet cross-section and / or gas jet strips in the exit cross-section of the gas from the gas cushion channel be provided in order to prevent the gas from flowing out of the gas cushion channel into or against to prevent the direction of travel of the web 10.

- patent claims -

Claims (13)

Claims 1. device for contactless carrying and guiding of enbahnen on a gas cushion, which is created by supplying a gas from a supply channel is maintained in a gutter, d u r c h e k e n n n n z e i c h -n e t that the total amount of gas for a section length from one compared to the section length short opening or from the supply duct that extends over the entire length of the section t18) impinges perpendicularly on the material web (10) to be carried. 2. Apparatus according to claim 1, characterized in that the angle (OL) between the side walls (16) of the gas cushion channel (14) and the horizontal is between 100 and 300. 3. Device according to claim 2, characterized in that the angle da3 (oC) is 250. 4. Device according to one of claims 1 to 3, characterized in that that at least the transition area from the supply channel (18) to the side walls (16) the gas cushion channel (14) has a hyperbolic cross-section. 5. Apparatus according to claim 4, characterized in that the Ryperbel to the upper edge of the side walls (16) in a straight line (20) with an angle of inclination (çt) passes over from something50. 6. Device for contactless carrying and guiding of webs of material on a gas cushion, which is produced by supplying a gas from a supply channel is maintained in a gutter, characterized in that at least one Part of the gas volume through slot nozzles or perforated nozzles or a combination of perforated and slot nozzles, which are inclined towards the material web (10), into the gas pile trough (32) flows in. 7. Apparatus according to claim 6, characterized in that the partial gas flows (26) can be generated by deflecting on a guide body (28). 8. Device according to one of claims 1 to 7, characterized in that that an outflow of the gas from the gas cushion channel (12, 32) in or against the flow direction of the web (10) in the inlet cross-section and / or in the outlet cross-section Gas jet bands is suppressed. 9. Device according to one of claims 1 to 8, characterized in that that the side walls (16) of the gas cushion channel (12, 34) in the region of the edges of the Web (10) are designed to be permeable. 10. The device according to claim 9, characterized in that the side walls (16) are provided with lamellae (40). 11. Device for the heat treatment of material webs, in particular Sheet metal strips according to one of claims 1 to 10, characterized in that da3 over and heat radiators are arranged under the web (10). 12. Device according to one of claims 6 to 11, characterized in that that the guide body (28) heat radiators (36) are attached. 13. Device according to one of claims 11 or 12, characterized in that that the gas after flowing out of the channel (14, 32) is deflected in such a way that the top of the web (10) is also acted upon.