DD296053A5 - blower - Google Patents

Abstract

The invention relates to a sheet guiding device for guiding flexible surface structures in processing machines, for example printing machines consisting of several incorporated in closed Leitflaechen Duesen, which are arranged below or above the Foerderweges and act pneumatically on the surface structure. The object of the invention to provide a sheet guiding device in processing machines, for example printing presses, with which both a suction effect and a support effect on the gefoerderten by the processing machine flexible surface is achieved, is achieved by the fact that the element centrally has a suction air acted upon suction bore and symmetrically to the suction bore a plurality of blowing air can be applied Blasduesen arranged. Fig. 2 {areas; Printing press; conveyance; pneumatics; Element; suction hole; blast nozzle; guide element; Grease; Processing machine; Blow; Suck}

Description

For this 4 pages drawings

Field of application of the invention

The invention relates to a sheet guiding device for guiding flexible sheet structures in processing machines, for example printing machines, consisting of several incorporated in closed guide surfaces nozzles which are arranged below or above the Forderweges and act pneumatically on the sheet structure

Characteristic of the known state of the art

In some processing machines, such as printing presses, the transport of the flexible sheet structure preferably takes place by means of grippers which grasp the flexible sheet at its leading edge and feed it to the individual functional groups. Only the front part of the flexible sheet formed by the gripper moves along the rectilinear or curved gripper track While the rear area may differ significantly from the prescribed trajectory, gravity, centrifugal forces, inertia forces as well as the wide range of influences such as pressure differences and turbulence may be due to this deviation of the arc from the gripper loading track Bahnfuhrung to disruptions in the processing process and quality degradation of the flexible sheet structures are sheet guiding devices in processing machines, such as printing press Thus, for example, the document DE-PS 31 35105 a consisting of Blasdusen sheet guiding device, the Blasdusen are incorporated in the sheet guide plate of a sheet-fed rotary printing machine from the Blasdusen a parallel air flow against the sheet travel direction between the bottom and baffle is blown, so that after It is disadvantageous that the arc is sucked through the blow jet, in the area of the same and carried at a small distance above the baffle, but in the rear part of the aerodynamic paradox a negative pressure between sheet and baffle the nozzle fully touches the baffle and thus can not be used in the operating mode perfecting and perfecting, because the sheet greases

With the device described in DE Gbm 8225956 the contact of the sheet with the guide surface in the rear part of the nozzle should be avoided For this two nozzles are arranged one behind the other in the same direction blowing, the rear nozzle at a steeper angle emanating the blow jet as the front of this The exit angle may be between 30 degrees and 90 degrees. It is disadvantageous that at an angle of 30 degrees, the jet emerging from the rear nozzle also creates a negative pressure in the rear part of the guide surface behind the nozzle and contact of the sheet with this guide surface occurs the jet at 90 degrees from the guide surface, so although the support effect is also present in the rear part of the guide surface, but the device is not able to capture a free at the leading edge bow exactly and force it into its Forderebene, as the The jet direction of the suction is exactly the opposite direction gswinkel of 45 degrees can not therefore perform the dual function of the device and remains a compromise solution

In addition, with the same jet direction of two nozzles lying one behind the other, the negative pressure generated in the jet by the first jet is saturated in the jet by the flow of the second jet, thereby also reducing the suction. This device thus does not guarantee a quality-compliant requirement with regard to greasing and exact sheet guiding

Object of the invention

It is an object of the invention to provide a sheet guiding device in processing machines, such as printing presses, can be promoted without contact and flutter-free by the printing machine with the flexible sheet.

Explanation of the essence of the invention

It is an object of the invention to provide a sheet guiding device in processing machines, for example printing presses, with which both a suction effect and a supporting effect on the conveyed through the processing machine flexible sheet is achieved.

According to the invention, this object is achieved in that the element has a central suction air acted upon with suction and symmetrical to the suction bore a plurality of blowing air can be applied with blowing nozzles are arranged.

The tuyeres are arranged at an exit angle of 90 degrees or less than 90 degrees in the element. To the suction hole is arranged one or more circles of nozzles. The nozzles may be formed extended in cross section upwards. The nozzles are associated with an air chamber. To the suction hole a leakage air line is provided.

The solution according to the invention has the advantage that at a small distance the flexible sheet can be conveyed through the processing machine without smearing.

The sheet guide avoids the frictional engagement between the fabric and machine parts. Even with a convex or concave curvature of the conveying path, the sheet is conveyed safely and without smearing through the processing machine.

This is achieved in that a special pressure profile is generated by the use of pressure and suction, which sucks the fabric against the air cushion.

The sheet guiding device also minimizes the required operating effort, since a setting on the respective print format is eliminated and an adjustment to the printed image (pressure-free corridors) is no longer necessary.

embodiment

The invention will be explained in more detail below using an exemplary embodiment. In the accompanying drawings show

1: Printing machine in side view (schematically)

Fig. 2: Pneumatic element in plan view

Fig.3: Pneumatic element in section (according to Fig.2)

Fig. 4: forces-distance diagram

5: Pneumatic element with obliquely arranged nozzles (top view)

Fig. 6: Pneumatic element according to Figure 5 in section

FIG. 7: top view of the conveying path (view X in FIG. 1)

Fig. 8: Top view of a modified embodiment

9 shows a section according to FIG

10 shows a plan view of a second modified embodiment

11: section according to FIG. 10.

Fig. 1 shows a schematic representation of a side view of a processing machine, which is designed here as a printing press.

The printing machine consists of the sheet feeder 1, one or more printing units 2 and the sheet delivery 3. The printing unit 2 consists of the printing, rubber and plate cylinder 4; 5; 6. Between the printing cylinders 4, a sheet guiding drum 7 is arranged. The conveying path 8 of the flexible sheet 9 from the sheet feeder 1 via the printing units 2 to the sheet delivery 3 is strongly drawn. Above or below the conveying path 8, at passages at which the flexible sheet 9 tends to come into contact with machine parts, for example guide elements 10, the sheet guiding device is arranged (see FIG. 1).

The sheet guiding device is designed as a pneumatic element 11 and is recessed into the closed guide elements 10 with the surface lying approximately in one plane. There are, see Figure 7, over the width and along the conveying path 8 a plurality of elements 11 next to and behind each other.

The single element 11 has the following structure. Centric in the element 11, a suction bore 12 is introduced. The suction bore 12 is connected via a suction air line to a vacuum generator, not shown.

Each suction hole 12 are associated with a plurality of nozzles 13. The blowing nozzles 13 can be designed as bores (FIGS. 2, 3) or slot-shaped (FIGS. 10, 11). The nozzles 13 can be arranged in one or more rows around the suction holes 12. The nozzles 13 open into an air chamber 14 which is connected to a compressed air generator, also not shown. The exit angle 15 of the tuyere 13 is identical to the jet direction.

The beam direction on the sheet 9 may be 90 degrees (Figure 3) or not equal to 90 degrees.

According to Fig. 5, the blast nozzles 13 are arranged such that the blast air jet of the four indicated blast nozzles 13 form a polygon 16, i. the blowing nozzles 13 direct a blown air jet to the respectively upstream blowing nozzle 13.

4 shows the force-distance diagram. In this case, h is the distance of the fabric 9 from the element 11, Ua the maximum possible suction height, h ₀ the force equilibrium distance and F _n the total force acting on the sheet 9.

8 and 9 show a modified embodiment of the pneumatic element 11. Here, starting from the suction bore 12, a leakage air line 17 is provided. The leakage air duct 17 is located centrally to the suction bore 12, which ends below the surface of the element 11, wherein the leakage air duct 17 merges sharp-edged with 180 degrees flow deflection in the suction hole.

10 and 11 show another modified second embodiment These elements 11 are designed as diffusers that is, the Blasluftdusen 13 are widened in cross-section to the surface, so that the exit velocity of the blast air jet is reduced At the same time the volume flow necessary for the positive force action remains constant The mode of action the sheet guiding device according to the invention is the following The flat structures 9 are singulated in the sheet feeder 1, and fed to the printing units 2, where they are printed After the last printing unit 2, the sheet formations 9 are stored in the sheet delivery 3 At the same time arranged on the abschmiergefahrdeten passages elements 11 are pneumatically applied, so sucked 12 air through the centrally arranged in the suction member 11 and blown through the Blasdusen 13 perpendicular or obliquely to the sheet 9 blowing air

If an element 11 is covered by the flat structure 9 required by means of a gripper, then a specific pressure profile is produced. The resulting total force F _n , which acts on the flat structure 9 and is qualitatively plotted in FIG. 4, shows a strong dependence on the distance h of the flat structure 9 from element 11

The curve of the total force Fn (see FIG. 4) can be divided into three distinct ranges. In the first range in which h is less than h ₀ , the positive force effect prevails, which is due to the blowing air emerging from the blow nozzles 13 due to the flow high overpressure arises so that a contact of the flat structure 9 with the guide elements 10 and thus a greasing is reliably avoided This assumes, however, that the sum of all imposed forces including the suction force is directed to the guide element 10 Since this dominant overpressure with linearly increasing distance h with a higher power decreases as the negative pressure caused by the suction opening, is in the range h ₀ smaller h is smaller h _a negative total force F _s generated in a claim of the flat narrow image 9, the flat formations 9 is sucked in by means of the gripper within this interval, the vertical distance h to the element 11 is reduced until all au In a sufficiently great distance h of the flat structure 9 from the guide element 10, above the maximum possible suction height h _A , only the radiation force constant over the distance h influences the force impressed the flow emerging from the Blasdusen 13 the flat structure 9 with a positive total force F _n In order to increase the maximum allowable suction height h _A and thus allow greater distances of the Forderweges 8 to the elements 11, or to enable the vanes 10, the flat structure 9 from 5.6, variants are shown which direct their beam from the blast nozzles 13 not perpendicular, but at a smaller angle than 90 degrees to the flat structure 9

In this way, not all of the radiant power, but only her perpendicular to the surface structure 9 share in the power balance, whereby the section hAbis h _{0 is} increased

The same effect of reducing the jet force acting on the flat body 9 is achieved by the second embodiment shown in FIG. 10, 11. The jet exit speed is delayed by the cross-sectional widening of the bladders 13 and the jet force is thus lower. At the same time, the positive force effect at h remains smaller h ₀ and the necessary volume flow constant

To improve the support effect of the pneumatic elements 11, FIGS. 8, 9 show a variant in which air can flow through a leakage air line 17, preferably in the equilibrium state of the sucked and truncated flat structure 9, so that the vacuum values remain minimal and the force equilibrium distance h _{0 is} increased while the suction height h _A does not decrease, during the suction of the flat structure 9 from high h h large h ₀ by the sharp-edged 180-degree transition of the leakage air duct 17 into the suction bore 12, the leakage air duct 17 is almost ineffective

Claims (7)

1. Sheet guiding device for guiding flexible sheet structures in processing machines, for example, printing machines consisting of several incorporated in closed vanes pneumatic elements acting below or above the Forderweges the flexible sheet material by means of air on the flat structures, characterized in that the element (11) centrally having suction air acted upon suction bore (12) and symmetrically to the suction bore (12) a plurality of blowing air acted upon Blasdusen (13) are arranged 2. sheet guiding device according to claim 1, characterized in that the Blasdusen (13) at an exit angle (15) of 90 degrees in the element (11) are arranged 3 sheet guiding device according to claim 1, characterized in that the Blasdusen (13) are arranged at an exit angle (15) kleiner90 degrees in the element (11) 4 sheet guiding device according to claim 1, characterized in that one or more circles of Blasdusen (13) are arranged around the suction bore (12) 5 sheet guiding device according to claim 1, characterized in that the Blasdusen (13) are formed widened in cross-section upwards. 6 sheet guiding device according to claim 1, characterized in that the Blasdusen (13) are associated with an air chamber (14). 7. sheet guiding device according to claim 1, characterized in that a leakage air line (17) is provided around the suction bore (12)