This application claims priority to German Patent Application 103 25 377.7, filed Jun. 5, 2003, which is hereby incorporated by reference herein.
The present invention is directed a device for sensing the position of an edge of a product, as well as to a method for sensing the position of an edge of a product.
During the process of printing sheets, in particular in a sheet-fed offset press, the sheets are supplied to the press from a sheet stack. When a single sheet is fed to the printing press, known methods heretofore provide for the sheet to be laterally aligned at the feeder along a guide edge. However, it is also possible for the sheet to be laterally aligned by actuator-driven displacement of the front sheet edge on the cylinder, thus during conveyance of the sheet. Such actuator-driven displacement is known, for example, from the German Application DE 196 18 030 and related U.S. Pat. No. 6,264,196, which is hereby incorporated by reference herein. In response to the actuator-driven displacement, the sheet is guided to a defined setpoint position, the actual position of the sheet being detected by sensors.
To ensure exact alignment of the sheet, the actual position of the sheet edge must be precisely determined. A device for sensing and controlling the edge position of a continuous web is already known from the German Application DE 36 37 874. When working with this device, a web is irradiated by an illuminating device that extends over a planar area. The light beams striking the web are reflected from there in accordance with the laws of reflection and fed to an electro-optical image sensor. The electro-optical image sensor scans a strip on the web by sequential lines, the strip also encompassing a partial area situated outside of the web. In this way, the width of the area situated outside of the web can be determined and, from this, in turn, the position of the web. However, this method can only be applied when the material web used is a material web that is sufficiently reflective in accordance with the laws of reflection. This is particularly not the case when working with transparent films.
From the German Application DE 101 36 871, a device is known for sensing the position of an edge of a sheet that is fed to a printing press. In this case, an opto-electronic measuring device is used, which is oriented orthogonally to the conveyance direction of the sheet.
The measuring device is mounted above the feedboard and has reflecting arrays which are able to detect a reflected beam. To enable problematic sheets to be detected, in particular transparent or high-gloss materials, the surface of the feedboard is additionally provided with contrast-enhancing means. To this end, the feedboard is specially finished in one partial area, in particular highly polished, chromium-plated, or provided with a reflective layer. However, the drawback when working with this device is that it is no longer possible to distinguish the materials themselves from the contrast-enhancing layer when the sheets to be measured have surface properties which correspond or nearly match those of a highly polished or chromed surface.
An object of the present invention is to provide a device and a method for sensing the position of an edge of a stock material, such as, for example, printing substrate, which are further optimized with regard to the measurability of various types of stock.
In one preferred embodiment of the present invention, a device for sensing a position of an edge of a stock being feed to a printing press is provided. The device comprises a light source arranged to illuminate a preselected area of the stock, and a preselected area adjacent to the stock, and a measuring device for recording reflected radiation caused by reflection of radiation of the illumination of the light source. In accordance with a feature of the present invention, at least a portion of the preselected area adjacent to the stock that is being illuminated by the light source, comprises a retro-reflecting surface. The light source includes a planar illumination source.
In another preferred embodiment of the present invention, a method for sensing the position of an edge of a stock being feed to a printing press is provided. The method includes the steps of providing a light source, utilizing the light source to illuminate with planar radiation a preselected area of the stock, and a preselected area adjacent to the stock, and further providing a retro-reflecting surface on at least a portion of the preselected area adjacent to the stock illuminated by the light source. According to a feature of the present invention, a measuring device is provided and utilized to measure radiation reflected by the retro-reflecting surface.
Referring now to the drawings, and initially to
Thus, the device according to the present invention is distinguished in that a retro-reflecting surface area is used to sense the position of an edge of a stock. This retro-reflecting area is provided at a location where the stock 20 is fed to the printing press. By illuminating both the stock, as well as the adjacent retro-reflecting surface area, the edge of the stock may be ascertained even in cases where the stock itself reflects specularly. This is because the retro-reflecting surface area reflects the incident light back in the direction of the incident radiation. If a sensor is provided in this direction for detecting the retro reflected radiation, then the radiation that is reflected outside of the stock into the retro-reflecting sensor system, may be uniquely detected. The stock itself, on the other hand, does not reflect any radiation into the sensor, since it either scatters the radiation or reflects the incident radiation specularly, in a different solid angle, in accordance with the laws of optics.
As shown schematically in the plan view of
According to a feature of the present invention, CMOS matrix elements or CCD matrices, arranged in a two-dimensional array, may be used as a stock image sensor. The imaging quality may be further improved, in particular the imaging contrast enhanced, when working with films, in that light that is linearly polarized in a suitable direction is used to illuminate the stock or sheet and the retro-reflecting area adjacent to the sheet. By using CMOS matrix elements as image sensors and with the aid of fast readout algorithms, it is possible to increase the measuring frequency. For example, the article entitled “CMOS Image Sensor with Cumulative Cross Section Readout” by Bums and Homsey (www.cs.yorku.ca/˜visor/pdf/CCDAIS03_CCS.pdf) and “A 640×512 CMOS Image Sensor with Ultrawide Dynamic Range Floating-Point Pixel-Level ADC” by Yang, Gamal, Boyd and Tian (IEEE Journal of Solid-State Circuits, Vol. 34, No. 12, December 1999) describe CMOS readouts, and are hereby incorporated by reference herein. This enables a plurality of measured values to be recorded per sheet, from which an average value may then be calculated, thereby enabling error measurements to be minimized.
Referring now to
Another exemplary embodiment of the present invention is shown in
Since it is possible to read out the individual photosensitive elements of the CMOS matrix 47, the number of pixels to be read out may be decidedly reduced by using fast readout algorithms, thereby enabling the measuring frequency to be clearly increased in comparison to a CCD matrix have the same number of pixels. By using parallel light, which is oriented in parallel to the x-z plane, disadvantageous influences caused by a sheet edge that is slightly curved in the z-direction, may be kept to a minimum; the quality, and the y-position of the shadow of the sheet edge cast on the retro reflecting surface 30, being only slightly affected. Moreover, optical power losses occurring within the system are minimized by using parallel light.
In addition to the embodiments illustrated in
In the preceding specification, the invention has been described with reference to specific exemplary embodiments and examples thereof. It will, however, be evident that various modifications and changes may be made thereto without departing from the broader spirit and scope of the invention as set forth in the claims that follow. The specification and drawings are accordingly to be regarded in an illustrative manner rather than a restrictive sense.
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