DE2343996A1 - METHOD AND DEVICE FOR THERMAL CUTTING OF PAPER, CARDBOARD OR THE LIKE. - Google Patents

Description

PATENT LAWYERS

MUNICH 22. WIDENMAYERSTRASSE 49 1 BERLI N-DAHLEM 33 PODBIELSKIALLEE 68

BERLIN: DIPL.-ING. R. MÜ LLE R-BÖRNER MUNICH: DIPL.-ING. HANS-H. WEY

2k

Winkler & Dünnebier

Machine factory and iron foundry 545O Neuwied am Rhein

Method and device for flame cutting of paper, cardboard or the like.

The invention relates to a method for flame cutting of paper, cardboard or the like, and a device for Implementation of this procedure.

The flame cutting of paper, cardboard or the like. Takes place usually by means of a knife or a set of knives. Knives and knife sets require a cutting device that they holds and leads during the cutting movement. The mechanical cutting device and the knives or knife sets under » are inevitably due to wear and tear, are in their structure relatively complicated and expensive and allow only a limited cutting speed and a periodic one Operation with only a limited cutting frequency because the tools have to be replaced for maintenance «

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BERLIN: TELEPHONE (O311) 76 39 07 MUNICH: TELEPHONE (O811) 22 88 8O

CABLE: PROPINDUS TELEX OI 84087 CABLE: PROPINDUS TELEX OB 24244

The invention is based on the object of a method As well as a corresponding device for shape cutting of paper, cardboard or the like. To create a fast Shape cutting and possibly also a high cutting frequency with the least possible mechanical effort Enable components.

This object is achieved according to the invention with regard to the method solved in that the cut shape using coherent radiation in the cut surface is holographic is mapped and that the mapping takes place until the radiated energy burned out the cut shape Has.

The inventive method is preferably with a Device carried out according to the invention a radiation comprises source for coherent radiation and a hologram which is irradiated or penetrated by the radiation and which directs deflected radiation onto the material to be cut,

Holograms are known per se. This is the fixed mapping of the interferences of a coherent one Radiation with radiation coming from an irradiated object. The interference is typical of the vom Object coming · Radiation and contain sufficient information to reconstruct the radiation coming from the object and thus a spatial image of the object. The image can be fixed by means of a photographic layer on a translucent support, e.g. a glass plate, or an opaque support, e.g. a metal plate. The object image is reconstructed by irradiating or radiating the

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Coherent radiation holograms. To the essentials One of the properties of a hologram is that it is spatial Can generate image and that each point of the hologram participates in the generation of each image point is. This means that a section of the hologram also generates a complete object image.

According to the inventive method is on the to Cutting paper, cardboard or the like. Imaged the desired cut shape by means of coherent radiation. The on that Radiation hitting the hologram has such a low energy density that the radiation does not destroy the hologram or damaged. Each point of the hologram directs the radiation onto the desired cut shape, in the points The energy density of the cut is so high that the material to be cut burns through accordingly the shape of the cut takes place. A shaped cut is thus carried out.

The device according to the invention has a hologram, that is either irradiated or irradiated. This hologram

the

is arranged relative to the material to be cut so that the illustration of the cut shape takes place in the plane of the material. Among the main advantages of the invention

The method or the device according to the invention, that the cutting process does not require any mechanical movement of any parts. This means that disruptions are eliminated due to wear and tear on mechanically moving parts. Furthermore, the cutting frequency is not subject to any restrictions due to the masses of the parts to be moved Cut will not progress along a cut line executed, but simultaneously for all points of the sectional shape or part of it. The type of cut shape can be

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arbitrarily complicated without affecting the cutting process would make it difficult. The hologram, which at the same time carries information and is a tool and therefore, for example, a conventional knife set and associated control devices etc., is comparatively cheap and easy to manufacture. In addition, another may Cut shape can be selected solely by replacing the hologram, so that a retrofitting of the cutting device is conceivable is easy. Finally, partial damage or soiling of the hologram does not yet mean that it has become unusable. Rather, it can be due to the fact mentioned that every point of the hologram irradiated every point of the cut shape, continue to be used until the contamination or damage so far it is possible that the energy density is no longer sufficient in all points of the cut shape.

The inventive method, which is also referred to below as called holographic flame cutting is suitable also for flame cutting of cardboard and for multi-layer cutting

When selecting and producing the hologram, it must be ensured that it is suitable for the radiation used, i.e. in particular that it is adapted to the wavelength of the radiation. Furthermore, it must be such that it can pass through the energy required for the cut is not destroyed during irradiation or radiography. If necessary, can this can be achieved by making the hologram and the cross-section of the beam falling on it so large ensure that the energy density in the hologram itself is sufficiently low.

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In a particularly advantageous manner, the method for Production of the blanks for envelopes, bags or Like. Apply. These blanks are usually cut from a running web of material; comes with it high cutting frequencies and the cleanest possible cut. This is with the inventive method particularly easy to reach.

In an advantageous embodiment of the device according to the invention it is provided that the radiation source consists of a laser. Lasers are particularly suitable for generating coherent radiation of high energy density. The use of a laser beam for cutting paper webs is already known per se (US Pat. No. 3 Al9,706). Here, however, a focused laser beam is guided along the cutting curve. CO “lasers and ruby lasers have proven to be particularly suitable for holographic flame cutting. However, in the case of infrared radiation, such as, for example, that of a CO ₂ laser, no transmission hologram can be used, but an incident light hologram must be used.

With regularly repeated flame cutting it can possibly be advantageous to operate the radiation source in a pulsed manner. The pulse duration of a laser beam is in usually between approximately one us and one ms. Such a short pulse duration and thus a correspondingly short cutting duration enables a very high cutting frequency

In an advantageous development of the invention, optically imaging elements can be provided in front of or behind the hologram, which together with the hologram effect the imaging, By means of such optical elements, for example, the radiation in front of the hologram can be enlarged in cross section,

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to decrease the energy density. I have another option the use of optical elements consists in arranging them behind the hologram in such a way that they reduce the image and thus increase the edge definition of the cut shape.

If the flame cutting takes place from a moving material web, the radiation source and hologram are at one preferred embodiment of the device according to the invention spatially fixed. In this case, the material web can be fed past the hologram intermittently. However, because of the short cutting duration and the possible high cutting frequency, the material web can also be cut continuously be moved past the hologram at a constant speed · Another possibility, the moving material web cutting consists in the fact that the radiation is carried along with the web during the cut. This is then indicated when the material speed is very high and / or the duration of the sonity is relatively long. The radiation can be carried along by optical elements behind the hologram and / or by moving the hologram and the radiation source.

In order to enable the device to be converted quickly, the hologram can advantageously be exchanged.

Spatially curved cut shapes can also be created by means of the hologram can be mapped. This means that, which may be advantageous, the cut surface is curved with one axis can be. This can ensure that the material web is guided over a roller, so that the cut surface remains flutter-free.

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234399a

When using optical elements to generate the Illustration of the sectional shape can consist of the same arrangement Optical elements, holograms and cut surfaces can also be used to produce the hologram, with only the pattern of the cut shape needs to be placed in the cut surface and an as yet unexposed hologram is used must become.

A preferred embodiment of the invention is shown schematically in Figures 1 to 3 of the drawings, which is explained in more detail below. Show it:

1 shows a perspective view of a device for flame cutting in a schematic representation;

2 shows a view of the device in the state during the generation of the hologram;

3 shows the device according to FIG. 2 in the operating state during the form of sonhood.

In the device shown in Fig. 1, the material web to be cut 1, ζ. B. paper, in the direction of the arrow at a constant, high speed in a per se known Moved wise. Above the paper web 1 there is a hologram 2 made of a radiation-permeable layer carrier with an exposed and developed photographic Layer, its composition and condition the hologram correspond. A radiation source 3, the high-energy coherent parallel radiation, is arranged above the hologram 2 sends out.

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The radiation source 3 is operated in a pulsed manner. Each impulse has a duration of 100yus. The radiation strikes the hologram 2, which in turn emits radiation whose characteristics correspond to the image of the cut shape 6 to be cut. Several points 5 of the hologram are shown in the illustration. Each of these points irradiates every point of the sectional shape 6. This is indicated in the figure by the fact that from each point 5 rays to three points 7 of the sectional shape selected as an example are drawn. The energy radiated onto each point of the cut is sufficient to burn a narrow strip of the material 1 corresponding to the cut and thus to produce the desired cut. The pulse duration is so small in relation to the feed speed of the paper web 1 that it does not move appreciably during the duration of the pulse. The next pulse is generated when the paper web has been advanced a predetermined distance. In this way, blanks can be continuously cut out of the paper web 1.

As can be seen from Figure 2, as is customary in holography, the laser beam 11 after deflection by a Deflecting mirror 12 by means of a beam splitter 13 in a Object beam 0 and a reference beam R split. The object beam 0 is via the deflecting mirrors 14 and 15 directed to the object. The reference beam R passes over the deflecting mirrors 18 and 19 on the photographic recording plate 10. The deflecting mirror 12 has diverging Properties! it serves to expand the beam. The beam splitter 13 is intended to divide the incident radiation into equal parts share.

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The get ο graph.! s oh the object to be recorded is present the intersection curve 17 »this is worked into the metal plate 16 as a slot. This board 16 is from Object beam 0 illuminated from below. Along the curve Shaped slot 17, light passes through the circuit board 16. Since the slot 17 is relatively narrow, this will be Diffracted light in all directions and exposed by this the photographic recording plate 10 at all points. With this light passing through the slot 17 the reference light R, which is reflected by the mirror 19, arrives becomes, to the interference and forms the hologram on the photo plate 20.

The arrangement of the circuit board 16 with the intersection curve 17 and that of the hologram is such that the hologram 20 is is in its final position with respect to the paper web 1. This results in a later mapping the intersection curve through the hologram exactly at the desired point.

The same optics are used for the reproduction device shown in FIG. 3 as for the recording of the hologram 20. In a known manner, care must be taken that the hologram plate 20 after its development with respect to the reconstruction optical elements 12, 13t 18 ^{and <} ^ 19 is reattached in exactly the same position. The hologram plate 20 illuminated by the reconstruction beam now reconstructs the cutting curve 21 on the paper web 1

Claims ι

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Claims (1)

Expectations 1.! Method of burning molds without paper or cardboard ^ - ■ 'or the like ,, characterized in that the sectional shape using coherent radiation in the Sohnittfläohe is imaged holographically and that the image continues until the radiated Energy burned out the cut shape. 2. Application of the method according to claim 1 for production of blanks for envelopes, bags or the like. 3 · Device for carrying out the procedure according to Claim 1 or 2, characterized by a radiation source (3) for coherent radiation and a hologram (2), which is irradiated or penetrated by the radiation and the deflected radiation on the to be cut Material (1) aligns. k. Device according to claim 3 »characterized in that the radiation source (3) is a laser, 5. The device according to claim 4, characterized in that the laser is a CO "laser. 6. Apparatus according to claim k, characterized in that the laser is a ruby laser. 7 · Device according to one of claims 3 to 6, characterized characterized in that the radiation source (3) is operated in a pulsed manner. -11- 509811/0157 8. Device according to one of claims 3 to 7t characterized by optically imaging elements in front of or behind the hologram (2). 9. Device according to one of claims 3 to 8 for shape cutting from a running web, characterized characterized in that the radiation source (3) and the hologram (2) are spatially fixed are. 10. Device according to one of claims 3 to 8 for Shape cutting from a running web, characterized in that the radiation during the Cut is carried along with the train. 11. Device according to one of claims 3 to TO, characterized in that the hologram (2) is interchangeable, 12. Device according to one of claims 3 to 11, characterized in that the cut surface is uniaxially curved. W / Gr / Hi 50981 1/0157 Blank page