EP1792860A2 - Vacuum web transport device for guiding a running web - Google Patents

Abstract

In a reduced pressure conveyor belt device for guiding a moving sheet (2), with an air-permeable endless transporting belt (5) guided in a loop (8) with upper and lower tracks (6, 7) and a reduced pressure source (9) to fix the sheet to the inside of a track (6), reduced pressure is applied by long gap ejector(s) (10, 11), each having an air jet injector (12) with air outlet nozzles (14) along the inlet side (15, 16) of the long gap (17, 18), under the inside of the sheet fixing track (6).

Description

The invention relates to a vacuum belt conveyor device for guiding a moving web, in particular a web insertion strip of a paper or board web, according to the preamble of claim 1.

Vacuum belt conveyors for guiding a traveling web are used in various industrial plants to securely hold a web in transit. This is especially true for paper and board machines, where the web is transferred from one machine section to another machine section, for example from the wet end to the dryer section or from the dryer section to the finishing section.

Out DE 100 09 188 A1 It is known to use vacuum belt conveyors in paper or board machines to facilitate threading the paper or board web into a machine for making, finishing or further processing such a web. When a paper machine is put into operation or when it starts again after a web break, a narrow ribbon or introduction strip is separated from the running web. This tape is transferred by means of the vacuum belt conveyor, for example, from the end of a machine section to the inlet area of a subsequent machine section. For this purpose, the conveyor device comprises an air-permeable, endless conveyor belt, which runs over two rollers and a suction box or vacuum box. As a result, the insertion strip is sucked and transported to the conveyor belt. To create vacuum or negative pressure within the suction box, a vacuum blower is provided. The vacuum blower comprises an impeller having an exhaust passage. The impeller is driven by a suitable motor. The suction box has one or more suction openings, via which the vacuum blower generates negative pressure in the interior of the suction box. A disadvantage is the complex and large-scale construction, which is also maintenance-prone and expensive to manufacture and in operation. The sealing of the suction box is also difficult.

Out DE 35 24 006 A1 a device for transporting and guiding the Bahnendaufführungsbandes in a paper machine is known, which consists of a arranged around two or more guide rollers conveyor belt, which is permeable to air and within which loop devices are mounted, with which at the one run of the conveyor belt, with the Endaufführband is transported, a negative pressure effect is achieved, whereby the Endaufführungsband is stapled to the said run and adhered to it. The negative pressure is generated by air blowing means mounted inside the loop, which comprise guide plates which extend substantially parallel to the plane of the conveyor belt and at which a dynamic negative pressure effect can be generated by air blows, with which the Endaufführungsband is stapled to the conveyor belt. The disadvantage is that for blowing the guide plates a fairly large amount of air is required, which is to be diverted and leads to undesirable blowing currents in the area around the device.

Out DE 299 24 658 U1 Finally, there is known a device for conveying and guiding an insertion strip of a web in a paper machine of the type mentioned, in which the device for generating a negative pressure effect has curved air flow guide surfaces along the conveyor belt, which generate a negative pressure in connection with Foil heads. By adjusting the angle of the air flow guide surfaces, the height of the negative pressure can be regulated. The disadvantages are overpressure areas in front of the foil heads.

The object of the invention is therefore to provide a vacuum belt conveyor device for guiding a running web, which is structurally simple and takes up little space.

This object is solved by the features of the characterizing part of claim 1.

In this way, a vacuum belt conveyor device for guiding a moving web, in particular a web insertion strip, created, the device for applying a negative pressure next to a small size has adapted to the purpose of construction, namely a rectangular shape. The suction power is high and adjustable in the longitudinal and transverse directions. Pressure drops between individual suction centers are minimized so that a substantially uniform vacuum across the width and / or length of the conveyor belt is adjustable to hold a web.

Preferably, a nozzle row arrangement of the at least one long-gap ejector extends transversely to the strip running direction and generates an air flow perpendicular to the band. The air flow is then simply downwards derivable, whereby obstructions are minimized by unwanted air currents in the area of the device.

A gap space of the at least one long-gap ejector preferably has a section with a narrowed cross-section in order to achieve a high degree of efficiency. If a lower efficiency is sufficient, the gap space can also be formed without a cross-sectional constriction.

The at least one long-gap ejector may also work in conjunction with a suction space, for which purpose a partition may be provided within the loop. The partition is preferably arranged in the longitudinal direction of the conveyor belt and at a distance below the run, which is provided for holding the web. As a result, an intake space above the dividing wall is separated from an outflow space below the dividing wall. The outflow space is formed in an area above the returning other strand and may be formed open or closed to the outside. If a plurality of long-gap ejectors are arranged one behind the other in the longitudinal direction, transverse dividing walls can also be provided which subdivide the suction space and possibly the outflow space into a plurality of chambers arranged one behind the other. Selectable vacuum profiles along the conveyor belt are adjustable in this way.

If a partition wall is provided, a passage can be provided in the latter, which passage is provided with an adjustable throttle. About the throttle, a flow rate can be determined and thus set a maximum vacuum level.

The arrangement of the at least one long-gap ejector can be carried out vertically working to the conveyor belt or at an angle to the conveyor belt.

The at least one long-gap ejector may have a gap space which has a cross-sectional widening on the outflow side. The outflowing air can thereby be given a better distribution.

The at least one long-gap ejector may have a gap whose flow path length is selectable. Consequently, the gap space can not only serve to draw in air for generating negative pressure, but can also simultaneously be used for targeted removal of air from the area of application of negative pressure. In order to further improve the suction, the air jet injector can be arranged in a converging formed entry region of the at least one long-gap ejector.

The orientation of the entry region of the long-gap ejectors or the direction of movement of the conveyor belt is selectable. The inlet region can be arranged transversely or obliquely to the direction of travel or in the direction of travel, with multiple long-gap ejectors being able to be arranged at a distance from or immediately adjacent to one another in order to form selectable negative-pressure fields. In particular, when a plurality of long-gap ejectors form a negative pressure strip in the direction of travel, only one row of long-gap ejectors, for example a center strip, can be provided or several rows of long-gap ejectors can be arranged parallel and spaced from one another, for example two edge strips.

Further embodiments of the invention are described in the following description and the dependent claims.

• Fig. 1 zeigt schematisch eine Draufsicht einer Unterdruck-Bandfördervorrichtung,
• Fig. 2 zeigt einen Schnitt A-A nach Fig. 1 für eine Unterdruck-Bandfördervorrichtung gemäß einem ersten Ausführungsbeispiel,
• Fig. 3 zeigt schematisch eine Draufsicht eines Langspaltejektors der Unterdruck-Bandfördervorrichtung gemäß Fig. 2,
• Fig. 4a zeigt einen Schnitt B-B des Langspaltejektors gemäß Fig. 3,
• Fig. 4b zeigt vergrößert den Bereich X von Fig. 4a,
• Fig. 5 zeigt eine perspektivische Ansicht des Langspaltejektors gemäß Fig. 3,
• Fig. 6 zeigt einen Schnitt A-A nach Fig. 1 für eine Unterdruck-Bandfördervorrichtung gemäß einem zweiten Ausführungsbeispiel,
• Fig. 7 zeigt einen Schnitt A-A nach Fig. 1 für eine Unterdruck-Bandfördervorrichtung gemäß einem dritten Ausführungsbeispiel,
• Fig. 8 zeigt einen Schnitt A-A nach Fig. 1 für eine Unterdruck-Bandfördervorrichtung gemäß einem vierten Ausführungsbeispiel,
• Fig. 9 zeigt schematisch eine Draufsicht einer Unterdruck-Bandfördervorrichtung gemäß einem fünften Ausführungsbeispiel,
• Fig. 10 zeigt schematisch eine Draufsicht einer Unterdruck-Bandfördervorrichtung gemäß einem sechsten Ausführungsbeispiel,
• Fig. 11 zeigt schematisch eine Draufsicht einer Unterdruck-Bandfördervorrichtung gemäß einem siebten Ausführungsbeispiel,
• Fig. 12a und 12b zeigen jeweils einen Schnitt A-A nach Fig. 1 für eine Unterdruck-Bandfördervorrichtung gemäß einem achten und neunten Ausführungsbeispiel.

The invention will be explained in more detail with reference to the embodiments illustrated in the accompanying drawings.

• 1 shows schematically a top view of a vacuum belt conveyor device,
• 2 shows a section AA according to FIG. 1 for a vacuum belt conveyor device according to a first exemplary embodiment,
• 3 shows schematically a top view of a long-gap ejector of the vacuum belt conveyor device according to FIG. 2,
• FIG. 4a shows a section BB of the long-gap ejector according to FIG. 3, FIG.
• 4b shows enlarged the area X of Fig. 4a,
• FIG. 5 shows a perspective view of the long-gap ejector according to FIG. 3, FIG.
• 6 shows a section AA of FIG. 1 for a vacuum belt conveyor device according to a second embodiment,
• 7 shows a section AA according to FIG. 1 for a vacuum belt conveyor device according to a third exemplary embodiment,
• 8 shows a section AA according to FIG. 1 for a vacuum belt conveyor device according to a fourth exemplary embodiment,
• FIG. 9 schematically shows a plan view of a negative pressure band conveying device according to a fifth embodiment, FIG.
• 10 is a schematic plan view of a vacuum belt conveyance apparatus according to a sixth embodiment;
• 11 is a schematic plan view of a vacuum belt conveyance apparatus according to a seventh embodiment;
• FIGS. 12a and 12b respectively show a section AA according to FIG. 1 for a vacuum belt conveyor device according to an eighth and ninth embodiment.

1 shows a vacuum belt conveyor 1 for guiding a traveling web 2, in particular a web insertion strip of a paper or board web. The vacuum belt conveyor device 1 comprises guide rollers 3 and 4, between which a conveyor belt 5 is arranged. The conveyor belt 5 is endlessly guided in a loop 8 with a top run 6 and a bottom run 7, as shown for example in FIG. The conveyor belt 5 is permeable to air and consists of a cloth with sufficient permeability or a material web with hole structure.

Within the loop 8 is a device 9 for applying a negative pressure on the inside of one of the run of the conveyor belt, here the top strand 6, arranged to hold the web 2 to the conveyor belt 5. The device 9 for applying a negative pressure is formed by means of at least one long-gap ejector 10, 11 each having an air jet injector 12, 13 with a plurality of air outlet nozzles 14 along the inlet side 15, 16 of the extended nip 17, 18 and the inlet side at a distance below the inside of the is positioned to hold the track provided Trumms 6. About laterally on the conveyor belt 5 subsequent supply lines 21, 22 of the air jet injector 12, 13 of the at least one long-gap ejector 10, 11 fed by an air source, not shown, to inject air into the associated extended nip 17, 18 can. The injected air flows at high speed through the air outlet nozzles 14, whereby air is sucked in on the inlet side 15, which is located in the head-side environment of the at least one long-gap ejector 10, 11. In this way, a negative pressure on the inside of the run 6 can be applied by one or more air nozzles are mounted below the belt 5. The pressure of the supplied air is adjustable, which can influence the suction power. If a plurality of long-gap ejectors 10, 11 are arranged one behind the other in the running direction, they can receive the same or different air supply, in order to thereby design individually adjustable suction power profiles in the transport direction T.

The design of the at least one long-gap ejector 10, 11 is shown in detail in FIGS. 3 to 5 for the one long-gap ejector 10. The following explanations apply to all other long-gap ejectors accordingly. Thereafter, the long-gap ejector 10 has a substantially rectangular shape and has an air jet injector 12. The jet injector 12 is formed by a nozzle-19, which is arranged in the gap longitudinal direction and generates an air flow in the gap 20 of the extended gap 17. The nozzle assembly 19 is preferably recessed with respect to the inlet side 15, whereby the air sucked in on the inlet side is directed into the gap 20. Preferably, the air jet injector 12 is seated in a converging inlet region 23 of the long-gap ejector 10, wherein the short side edges 24, 25 of the extended-nip 17 are preferably rounded.

The extended gap 17 of the long-gap ejector 10 can delimit the gap 20 with parallel surfaces from the inlet side 15 to an outlet side 26, that is to say extend without a narrowed cross-section (compare FIGS. 12a, 12b). It is preferred to form the gap 20 with a narrowed cross-section for a high efficiency. The inlet region 23 with converging side surfaces then extends below the air jet injector 12. The constriction in the cross section of the extended nip 17 promotes the formation of a closed flow and thus an advantageous sealing of the Luftstrahlejektors 12. The suction of a long-gap ejector 10, 11 at the inlet side 15 is controllable via the fed air flow and by the shape of the extended gap 17 between the inlet side 15 and outlet side 26. Die Länge des Long gap 17 in the flow direction is selectable and opens up an advantageous discharge of air.

At the outlet side 26, the extended gap 17 is preferably formed with an enlarged cross-sectional portion 40, whereby the outflow behavior of the long-gap ejector 10 is improved with respect to a wide air outlet distribution. Even with a narrowed cross-section of the extended nip input and / or output side of the extended nip 17 preferably has a portion with parallel side surfaces, which can make up about 50 to 80% of the total length of the extended nip 17 in the flow direction between the inlet side 15 and outlet side 26. The extended nip 17 thus forms a guide channel for the air flow with a selectable flow path length.

In the illustrated in Fig. 2 the first embodiment of a vacuum belt conveyor device comprises the device 9 for applying negative pressure two long-gap ejectors 10, 11, which are arranged in the transport direction T at a distance one behind the other. The number of juxtaposed long-gap ejectors 10, 11 can be selected. The distance from the inside of Trumms 6 is also selectable and depends on the intake. A minimum distance ensures that a suction area, although local, but sufficiently flat. The extent of the extended nip 17 in the longitudinal direction of the gap can be selected as a function of a width of the conveyor belt 5, so that it is sucked over the entire width of the conveyor belt 5. In the transport direction T, the long-gap ejector (s) 10, 11 can be arranged at selectable locations, that is to say be positioned where a suction characteristic is desired. The respective air jet injector 12 with the associated nozzle assembly 19 preferably extends transversely to the direction of belt travel T and generates an air flow vertically to the belt 5. The long-gap ejectors 10, 11 are arranged here working perpendicular to the conveyor belt 5.

For positioning the at least one long-gap ejector 10, 11, a holder 27 is provided, which holds the long-gap ejectors 10, 11 stationary in the loop 8. The long-gap ejectors 10, 11 can furthermore be arranged freestanding in the loop 8. The holder 27 may be formed by a frame of the device 1, in which the guide rollers 3, 4 are mounted.

The conveyor belt 5 is moved in the transport direction T by at least one driven deflection roller 3, 4. According to FIG. 2, a drive motor 28 is provided for the deflection roller 3 for this purpose. To support the conveyor belt 5 on the loop between the guide rollers 3, 4 support grid, not shown, may be provided.

According to a second exemplary embodiment of the vacuum belt conveying device shown in FIG. 6, a dividing wall 29 is arranged within the loop 8. The partition wall 29 separates an intake space 33, 34, in which the inlet side 15 of the at least one long-gap ejector 10, 11 is arranged with its respective inlet, from an outflow space 35, 36, in which the outlet side 26 of the at least one long-gap ejector 10, 11 with its respective outlet is arranged. The partition wall 29 preferably extends substantially parallel to the conveyor belt 5. The suction chamber 33, 34 preferably forms an upper chamber and the outflow space 35, 36 a lower chamber, which are bounded laterally by cover plates 31, 32 with respect to the guide rollers 3, 4th

The suction chamber 33, 34 is bounded at the top by the run 6 of the air-permeable conveyor belt 5. Alternatively, the limitation can be made upward through a perforated plate on which the run 6 runs out. The distribution as well as the opening widths of the holes allow influencing the negative pressure characteristic on the inside of the run 6. The outflow space 35, 36 is bounded below by the returning Trumm 7. Are more Long-gap ejectors 10, 11 arranged, for example two as shown in Fig. 6, the long-gap ejectors 10, 11, a suction chamber 33, 34 and an outflow space 35, 36 assigned. By means of a transverse partition wall 30, the subdivision of the suction chambers 33, 34 and outflow spaces 35, 36 is possible. The at least one long-gap ejector 10, 11 sucks in the air from the respective intake space 33, 34, whereby an intake field corresponding to the intake space 33, 34 is applied to the inside of the run 6. The distance of the inlet side 15 of the at least one long-gap ejector 10, 11 from the inside of the run 6 can be selected to be greater than in the freestanding long-gap ejector 10, 11 shown in FIG. 2. In order to suck the air from the respective intake 33, 34 as evenly as possible the inlet side 15 is preferably positioned in a central region of the suction space 33, 34. Incidentally, the above statements on the first embodiment apply here accordingly.

According to one shown in Fig. 7 third embodiment of the vacuum belt conveyor device 1, an adjustable throttle 37, 38 is arranged in the partition wall 29. Via the throttle 37, 38, a flow rate between a suction chamber 33, 34 and a discharge chamber 35, 36 determined and thus a maximum vacuum level in a suction chamber 33, 34 are set. A maximum negative pressure in the suction space 33, 34 can be defined via such a bypass between intake space 33, 34 and outflow space 35, 36. From a certain negative pressure value, no further negative pressure builds up, since then the bypass flow via the throttle 37, 38 corresponds to the suction flow. A certain pressure difference is adjusted. The vacuum level is also adjustable. The risk that especially wet paper or board webs are damaged on the conveyor belt 5 by over-suction, therefore, does not exist. Each intake chamber 33, 34 with associated outflow space 35, 36 is preferably associated with a throttle 37, 38. In addition, the drive power of the motor 28 can be kept small by limiting the vacuum level. Incidentally, the above statements apply to the first and second embodiments accordingly.

The illustrated in Fig. 8 fourth embodiment of the vacuum belt conveyor device 1 differs from the third embodiment shown in Fig. 7 in that the at least one long-gap ejector 10, 11 is not arranged perpendicular to the conveyor belt 5 working, but at an angle to the conveyor belt working is arranged. The long-gap ejectors 10, 11 are inclined or tilted to the transport plane of the conveyor belt 5. The suction is the outflow with respect to the transport direction T leading or trailing formable. Incidentally, the above statements on the other embodiments apply here accordingly.

9 to 11 embodiments of the vacuum belt conveyor device 1 relate to different arrangements of at least two long-gap ejectors 10, 11 with respect to the running direction T. In the fifth embodiment according to FIG. 9, a first long-gap ejector 10 is positioned transversely to the running direction T. while a second spaced-apart long-gap ejector 11 is disposed obliquely to the transporting direction T. The order can also be reversed. In the sixth embodiment according to FIG. 10, both long-gap ejectors 10, 11 are arranged obliquely to the transport direction T. The angle to the transport direction T is selectable depending on the choice of the vacuum profile that can be generated thereby. In the seventh embodiment according to FIG. 11, the long-gap ejectors 10, 11 are arranged in a row one behind the other, forming a suction strip 39. As shown in FIG. 11, this suction strip 39 can form a median strip. Alternatively, an edge strip or edge strips on both sides may be provided. Incidentally, the above statements apply to the embodiments one to four here accordingly.

Figures 12a and 12b show an eighth and ninth embodiment of the vacuum belt conveyor device 1, which differ from the above embodiments in that the extended nip 17, 18 has no cross-sectional constriction, that has parallel side walls. The efficiency is lower, so that the long-gap ejector 10, 11 is preferably arranged closer to the inside of the run 6 of the conveyor belt 5. Incidentally, apply to the eighth Embodiment of FIG. 12a, the embodiments of the first embodiment of FIG. 2 accordingly. For the ninth exemplary embodiment according to FIG. 12b, the statements relating to the third and fourth exemplary embodiment according to FIGS. 7 and 8 apply correspondingly.

According to another embodiment, not shown, the vacuum belt conveyor device 1 can also operate rotated through 180 °, i. the negative pressure on the returning Trumm be applied with appropriate rotation of the long-gap ejectors and reversal of the transport direction.

Claims (23)

Vacuum belt conveyor device for guiding a moving web (2), in particular a web insertion strip of a paper or board web, with an air-permeable conveyor belt (5) endlessly guided in a loop (8) with upper run (6) and lower run (7), and one inside the loop (8) arranged device (9) for applying a negative pressure on the inside of one of the run (6) of the conveyor belt (5) for holding the web (2) on the conveyor belt (5), characterized in that the device ( 9) for applying a negative pressure by means of at least one long-gap ejector (10, 11) each having an air jet injector (12) with a plurality of air outlet nozzles (14) along the inlet side (15, 16) of the extended nip (17, 18) and is positioned on the inlet side at a distance below the inside of the run (6) provided for holding the web (2). Vacuum belt conveyor device according to claim 1, characterized in that the at least one long-gap ejector (10, 11) generates a flow in a gap space (17, 18) via a nozzle column (19) arranged in the gap longitudinal direction. Vacuum belt conveyor according to claim 2, characterized in that the gap space (20) is formed with a narrowed cross-section. Vacuum belt conveyor according to one of claims 1 to 3, characterized in that within the loop (8) a partition wall (29) is arranged, which has a suction space (33, 34) in which the inlet side (15, 16) of the at least one Langspaltejektors (10, 11) is arranged by a discharge space (35, 36) in which an outlet side (26) of the at least one long-gap ejector (10, 11) is arranged separates. Vacuum belt conveyor according to claim 4, characterized in that the suction space (33, 34) and outflow space (35, 36) has transverse walls (30) between adjacent long-gap ejectors (10, 11). Vacuum belt conveyor according to claim 4 or 5, characterized in that the suction chamber (33, 34) for limiting a negative pressure via at least one throttle (37, 38) with the outflow space (35, 36) is connectable. Vacuum belt conveyor according to claim 6, characterized in that the at least one throttle (37, 38) in a partition wall (29) between the suction chamber (33, 34) and outflow space (35, 36) is arranged to control a flow rate. Vacuum belt conveyor device according to one of claims 1 to 7, characterized in that the at least one long-gap ejector (10, 11) perpendicular to the conveyor belt (5) is arranged to operate. Vacuum belt conveyor according to one of claims 1 to 8, characterized in that the at least one long-gap ejector (10, 11) is arranged to operate at an angle to the conveyor belt (5). Vacuum belt conveyor according to one of claims 1 to 9, characterized in that the at least one long-gap ejector (10, 11) each having a gap space (20) having an outlet portion (40) with expanded cross-section. Vacuum belt conveyor according to one of claims 1 to 10, characterized in that the at least one long-gap ejector (10, 11) each has a gap space (20) with a selectable flow path length. Vacuum belt conveyor device according to claim 9, characterized in that the flow path length of the gap space (20) with a narrowed cross section is 50 to 80% of the total flow path length of the gap space (20). Vacuum belt conveyor according to one of claims 1 to 12, characterized in that the air jet injector (12) in a converging inlet region (23) of a long-gap ejector (10, 11) is arranged. Vacuum belt conveyor device according to one of claims 1 to 13, characterized in that the at least one long-gap ejector (10, 11) is arranged transversely to the running direction of the conveyor belt (5). Vacuum belt conveyor according to one of claims 1 to 14, characterized in that the at least one long-gap ejector (10, 11) is arranged obliquely to the running direction (T) of the conveyor belt (5). Vacuum belt conveyor according to one of claims 1 to 14, characterized in that a plurality of long-gap ejectors (10, 11) in the running direction (T) of the conveyor belt (5) are arranged adjacent to each other. Vacuum belt conveyor according to claim 16, characterized in that, depending on the running length of the conveyor belt (5) at least two long-gap ejectors (10, 11) in the running direction (T) of the conveyor belt (5) are arranged at a distance from each other. Vacuum belt conveyor according to claim 16 or 17, characterized in that the long-gap ejectors (10, 11) are arranged with the gap longitudinal direction in the running direction (T) of the conveyor belt (5) to form at least one sucking strip (39). Vacuum belt conveyor according to one of claims 1 to 18, characterized in that the at least one long-gap ejector (10, 11) has an inlet region with rounded short side edges (24). Vacuum belt conveyor according to one of claims 1 to 19, characterized in that the at least one air jet injector (10, 11) via laterally on the conveyor belt (5) arranged feed lines (21, 22) is fed. Vacuum belt conveyor according to one of claims 1 to 20, characterized in that an outflow space (35, 36) is capsuled for a controllable discharge of the outflow air. Vacuum belt conveyor device according to one of claims 1 to 21, characterized in that via a supply line (21, 22) the at least one long-gap ejector (10, 11) air can be fed, and the pressure of the air is adjustable. Vacuum belt conveyor device according to claim 22, characterized in that a plurality of long-gap ejectors (10, 11) are arranged adjacent to one another, and the supply lines (21, 22) air can be supplied with a respectively adjustable pressure.

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