DE29615294U1 - Device for contactless sheet guidance in a sheet printing machine - Google Patents

Description

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29.08.96

Device for contactless sheet guidance in a sheet-fed printing machine

The innovation relates to a device for contactless sheet guidance in a sheet-fed printing machine according to the preamble of patent claim 1.

Such a device is known from DE-PS 19 07 083, in which blowing air nozzles with a cross section in the form of an annular gap sector and with an air guide surface that is inclined downwards relative to the guide surface and delimits the annular gap sector opposite the guide surface are provided in a guide plate. The blowing air nozzles of the known arrangement are punched into a guide plate with tongue-shaped incisions and generate a directional air flow with a flat angle pointing in the conveying direction against the sheet that is to be transported floating over the guide surface. The geometric bottleneck for the air flowing through is located at the air outlet point. This throttle point is followed by a diverging guide surface that acts as a diffuser, and in this area a negative pressure typical of a diffuser is created, which sucks the sheet onto the guide surface formed by the tongue-shaped incision. Due to this suction, contactless sheet guidance is no longer possible. As a result, scratches and smearing occur on the side of the sheet that communicates with the guide device. The effect of the arrangement known from DE 41 13 465 Al is also comparable.

The innovation is based on the task of designing the blowing air nozzles of a device with the features mentioned above in such a way that the emerging blowing air does not have any negative pressure zones that disrupt the even air flow under the sheet to be conveyed and ensures contact-free sheet guidance. ■

According to the innovation, a solution to this problem is that the flow direction of the blowing air exiting the blowing air nozzle forms an angle with the sheet guiding device (greater than 45 degrees). Accordingly, the blowing air hits the sheet guiding device at such an angle of

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29.08.96

bottom against the floating sheet. This significantly reduces the suction zone at the edge of the nozzle and its effect is negligible. This is due to the fact that impulse forces come into effect when the air hits the sheet, which counteract the effect of the suction zone.

To achieve the desired goal, the blowing air nozzle or nozzles are formed by embossing with an air guide surface that rises steeply in the direction of the sheet travel and forms an obtuse angle with the sheet guide surface in a vertical cutting plane parallel to the sheet travel direction. The effect of an air guide surface that is curved in the cutting plane mentioned is supportive.

&ogr; The drawing shows an example of the innovation. It shows:

Figure 1 shows a longitudinal section parallel to the sheet travel direction through a blowing air nozzle with a steep exit angle,

Figure 2 is a plan view of a blowing air nozzle formed by forming a tongue-shaped incision,

Figure 3 shows a longitudinal section through a further embodiment with an additional opening compared to Figure 2 and

Figure 4 is a plan view of the embodiment in Figure 3.

The sheet guide surface 1 for the contact-free guidance of a sheet 2 floating on an air cushion is formed by the surface of a guide plate 3. In this guide plate 3, blowing air nozzles 4 are distributed over the sheet guide surface 1 at a distance from each other. Each blowing air nozzle 4 is connected by a

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' 29.08.96

straight or curved incision 5 of the guide plate 3 and formed from this guide plate by embossing downwards opposite the sheet guide surface 1, so that in a vertical cutting plane through the middle of the blowing air nozzle 4 parallel to the sheet travel direction a lower blowing air guide surface 6 is created, which in the said plane encloses an angle alpha with the sheet guide surface of greater than 45°, preferably 60°. The blowing air emerging from the blowing air nozzle 4 is thus directed steeply against the underside of the sheet 2 to be conveyed, as the arrow symbols in Figure 1 illustrate. This is achieved by the air emerging from the blowing air nozzle 4 having a vertical flow component that is greater than the tangential (horizontal) flow component to the sheet. Figure 2 shows a top view of a blowing air nozzle 4 in conjunction with a circular arc-shaped incision 5 and a blowing air guide surface 6 that widens in the direction of travel of the arc, but using the features of the invention, other forms of blowing air nozzle are also suitable for avoiding a negative pressure zone or at least reducing it to a minimum value at which smearing no longer occurs. The blowing air nozzle 4 shown in the example leads to an overpressure in the flushing zone during operation, which compensates for a possible negative pressure effect.

A special form of implementation of the features of the invention is a blowing air nozzle 4 with a sheet guide surface 6, which has an arc-shaped contour in the vertical cutting plane through the center of the blowing air nozzle parallel to the sheet transport direction, in which, as shown in Figure 1, the radius of curvature R is 2 to 5 times the sheet thickness t.

In the embodiment shown in Figures 3 and 4, the vertical flow component of the nozzle blowing air is increased compared to the horizontal component by providing an additional opening in the area of the tongue 6, through which a smaller additional amount of blowing air is blown essentially vertically against the sheet compared to the main nozzle flow. By shaping the tongue-shaped incision, a blowing air nozzle 4 is also created in the form of an annular gap sector, to which an ascending air guide surface 6 is connected in the direction of the sheet travel. In a vertical cutting plane parallel to the sheet conveying direction, this has in the air guide surface 6 according to the

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Representation in Figure 3 has additional openings 7 or 8, so that the blowing air from the blowing air nozzle 4 directed from below against the sheet 2 to be transported is directed at an obtuse angle against the underside of the sheet 2.

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LIST OF REFERENCE SYMBOLS

1 Sheet guide surface 2 arc 3 Baffle 4 Blowing air nozzle 5 incision 6 Air guide surface 7 opening 8th opening alpha angle

Claims (6)

toruur _ 6 _ A-1776 Protection claims: 1. Device for contactless sheet guidance in a sheet-fed printing machine, in which blowing air nozzles with an air guiding surface lowered obliquely downwards from the sheet guiding surface, which delimits a cross-section of the blowing air nozzle lying obliquely to the sheet guiding surface, characterized in that the flow direction of the blowing air emerging from the blowing air nozzle (4) encloses an angle (alpha) with the plane of the sheet guiding surface (1) and is directed steeply from below against the sheet, wherein a vertical directional component of the blowing air jet is greater than a horizontal directional component. 2. Device according to claim 1, characterized in that the blowing air nozzle (4) has an air guide surface (6) which is curved in a vertical cutting plane parallel to the sheet transport direction. 3. Device according to one of claims 1 to 2, characterized in that blowing air nozzles (4) with an outlet profile which, in plan view, has the shape of an annular gap sector are provided in a guide plate (3). 4. Device according to claim 1, characterized in that a small opening (7) for a blown air outlet is additionally arranged in the air guiding surface (6). 5. Device according to one of the preceding claims, characterized in that the flow direction of the blowing air exiting from the blowing air nozzle (4) coincides with the tour ·* " -7- ·'■ " ~ A-1776 Plane of the sheet guide surface (I) or the underside of the sheet to be transported (2) encloses an angle (alpha) with its apex pointing in the sheet conveying direction. 6. Device according to claim 2, characterized, an opening which is small in cross-section compared to the cross-section of the blown air nozzle (4) is arranged in the air guiding surface (6) formed by the tongue-shaped incision (5).