DE19633557A1 - Hand measuring instrument for colour print spectra - Google Patents

Abstract

A spectrum measuring instrument for hand use in the correction of colour printing and proofs has a measuring head (1) in which the opening (4) for the sensor (5) is made in the side of the housing (3). This is linked to a monolithic spectrum analyser (12) comprising a curved screen (14) and diode (15) fixed to the base plate (2). This is placed on the face (7) of the printed item being examined. The instrument has no inner or outer moving elements. It is compact and easy to handle, simple to construct and inexpensive. It can be used to measure colour properties in very small areas with adequate precision, using only slight hand shifting to cover a wider field.

Description

The invention relates to a spectral hand-held measuring device for remission measurements on colored printed sheets and test forms, consisting of a device housing with device base plate, a measuring head with measuring light lamp for generating the Measuring light and with means for collecting the remitted from the measuring surface Light, an optoelectronic that is operatively connected to the measuring head Device for spectral decomposition and evaluation of the remitted light and electronics for the digital processing of the measurement signals.

In addition to densitometry, using so-called densitometer devices is carried out, the colorimetric measurement wins in the graphic Industry is becoming increasingly important. The colorimetric measurements are made in Contrary to densitometric measurement, usually not on special ones Control fields, but mainly directly in the printed image or on colored patterns. The color measuring devices can therefore with a larger measuring opening and do not necessarily have to be the high ones Color reflected densitometer requirements in terms of speed and meet easy handling. In known color measuring devices, according to the so-called three-area process (see DIN 5033 Part 6), the Evaluation of the remitted measurement light by three photodiodes, which are completely analog arranged to the three or four photodiodes of a colored incident densitometer can be. The same applies to spectrally measuring color measurement devices (cf. DIN 5033 part 4) if the spectral decomposition and evaluation by individual Photodiodes are carried out, which are equipped with narrow-band interference filters.  

However, there are already 16 or even 32 diodes in the measuring head, when the visible range of light is resolved in steps of 20 or 10 nm shall be. Because of the constructive difficulty and the costs In the case of multi-filter devices, one is usually limited to a spectral one 20 nm resolution.

Devices that offer a spectral resolution of 10 nm or less Have diffraction gratings. The light spectrally broken down by the diffraction grating becomes projected either onto a single diode or onto a row of diodes. In the EP 0 331 629 describes a spectral hand-held measuring device, of which here is assumed, the rotatable diffraction grating the spectrally split light projected onto a single diode by a swiveling movement. The technical The effort of such a solution is considerable, especially in the example described the pivoting movement of the grille with the motorized extension and retraction of the Measuring head is coupled.

The currently known spectral color measurement devices with high-resolution Diffraction gratings are in themselves an acceptable solution for that fairs mentioned at the beginning in the picture and on samples. In contrast, they are for measuring in small control fields is less suitable. Most devices are too big and too heavy for precise and fatigue-free positioning on small control fields. In addition, the known devices, such as mentions movable measuring heads that either move out of the housing by motor and retracted or with the housing by one Joint mechanism can be lowered to the measuring field. Before leaving  or lowering the measuring head, the control panel must be on the device fortified viewfinder, which is not only cumbersome and is time consuming, but can also lead to the fact that after targeting Device is moved unintentionally, which then accidentally on one other than the intended location.

Measuring with color measuring devices in small and many control fields is too has become an important task in the graphic arts industry ever since of the Color Management (compare Graphical Palette No. 4/95, ISSN 0936-806X, S. SW1 to SW8: Color Management etc.) the color adjustment of the digital proofing devices to the printing presses using test forms is made. The test forms are printed on in multi-colored halftone printed on the presses. Then the test forms evaluated colorimetrically and the CIE values measured in the control fields evaluated in a computer program to a so-called color profile. The digital proofing device corrects the color profile to produce images can match the color of the images created on the press to match. The digitally produced proof images show this in advance expected print result and are the role model for the printer Setting the press.

The color profile is required to make all perceptible colors possible can correct completely. So the quality of the color profile largely depends on the number of measuring fields on the test form, because many measuring fields one enable fine gradation of colors. The in the standard ANSI IT8.7 / 3-1993  Specified test form contains 928 different 6 × 6 mm color fields. A fast, easy and largely from the precise placement error-free evaluation of this or similar test forms is currently with the available spectral handheld measuring devices are not possible. Besides, these are Devices, as mentioned above, constructively due to their adjustable measuring heads complex and also correspondingly large in volume and due to the adjustment mechanism heavy, which also stands in the way of easy handling.

The invention is therefore based on the object, a spectral Handheld meter of the type mentioned to improve that without external and internal moving elements, i.e. constructively simple, handy in terms of size, compact and inexpensive is formed, nevertheless a precise placement on relatively small measuring fields and a quick and easy measurement with the proviso that the spectral handheld meter for performing measurements on the small Measuring fields only a displacement movement in the level of the test form needed in order to make the necessary operating movement at all limit achievable minimum.

This task is with a spectral hand-held device of the type mentioned Kind according to the invention solved in that with its the measuring opening having part protruding laterally from the housing and the spectral device formed from a diffraction grating and a row of diodes are connected by an optical fiber, and the measuring head and the spectral Device are firmly arranged on the device base plate, and the measuring opening  of the measuring head in the plane of the bearing surface of the device base plate is arranged.

The spectral device is a monolithic unit Electronic module similarly designed, in such a way that the optical and electronic components in their own small housing are arranged and included.

In contrast to devices with this design according to the invention movable measuring heads the movement requirement when changing from one Control panel is reduced to the absolutely necessary level to the next, d. that is Device is always, without having to adjust anything, after switching on ready to measure and only has to be moved from measuring field to measuring field in parallel. There the measuring head is not somehow trained and ultimately takes up space Adjusting mechanism required, it can now be simple, compact and simple cost-saving together with the optoelectronic, monolithic Device to be arranged on or on the device base plate, the The measuring head can only be optically connected to this device and this again electrically with the processing electronics. Under "handy compact" is a size of the elongated box-shaped housing to understand that not significantly behind and / or forward a hand guiding the device towered over.

The basic requirement for the constant readiness of the handheld measuring device, that the measuring opening of the measuring head in the plane of the support side  Surface of the device base plate is or extends in this is also then guaranteed if the device base plate is advantageous on the support side at least three spacer elements holding them parallel to the support plane is provided, which will be explained in more detail. These spacers provide namely for the measuring opening to be dirty or still dirty damp test form template can not be affected and also, because the device base plate no longer lies over the entire surface of the displacement of the Device significantly easier and can also be made more sensitive will.

The spectral hand-held measuring device according to the invention and further advantageous ones Embodiments are described below with reference to the drawing of exemplary embodiments explained in more detail.

It shows schematically

Figure 1 shows the handheld measuring device in side view of the measuring head;

Fig. 2, the hand-held instrument in plan view and in assembly or supporting on a a plurality of control fields having test form;

Fig. 3 is a plan view of the device base plate with the measuring head arranged thereon and the monolithic, optoelectronic device connected to it by light guide

Fig. 4 greatly enlarged a section through the measuring head taken along line IV-IV in Fig. 3.

FIG. 1 shows the side view of the device facing the user, specifically in the preferred embodiment in which the device base plate 2 is provided with the spacer elements 6 .

With 1 the measuring head is designated, which is firmly screwed to the device base plate 2 . The device is covered by the housing 3 . For measuring, the device is placed with its measuring opening 4 on the selected control field, which, due to the conical shape of the part 5 of the measuring head 1 protruding laterally from the housing, can also be carried out precisely on small control fields, since the lower outer half-round design Cross section of part 5 is smaller than the control field to be measured. The conical design of part 5 takes into account that such measurements are usually made by a person sitting at a table and the operator has the device with the measuring head side in front of him. There is no movement of the measuring head 1 relative to the housing 3 . The device is simply moved as a whole with its measuring opening 4 from control field to control field, which can be carried out quickly and precisely. In contrast to devices with a movable measuring head, regardless of whether it is extendable or lowerable, the sequence of movements when changing from one control field to the next is reduced to the absolutely necessary extent.

The three or more spacer elements 6 made of easily slidable plastic ensure that not the entire device base plate 2 rests on the printed sheet and the device can be moved sensitively with little force. With the height of the spacer elements 6 , which is approximately 0.5 to 1 mm, there is also a smaller defined distance between the measuring opening 4 of the measuring head 1 and the measuring plane, thereby avoiding that the measuring head 1 touches the printed sheet. As shown, the spacer elements 6 are advantageously somewhat rounded toward the bottom surface.

Fig. 2 shows the device in plan view with the display field 8 for the display of the measured values and the controls 8 '. 9 denotes the test form shown as a section, which is divided into a plurality of control fields 10 . The device can be connected to a computer via the connection socket 11 . If the device is always to be used in connection with a computer, the display field 8 can be omitted and the monitor of the computer can be used for the display. Without the display, the spectral hand-held measuring device even achieves the compact dimensions and ease of handling that correspond to the computer input devices known as mice.

Fig. 3 shows the arrangement in plan view of the measuring head 1 and the spectral monolithic device 12 on the instrument baseplate 2. This device base plate 2 preferably consists of a stable metal plate on which all elements are built and fastened. With the light guide 13 , the remitted measuring light is guided from the measuring head 1 to the diffraction grating 14 and, after spectral decomposition, is projected onto the diode array 15 , which, for. B. consists of 256 diodes. The analog signals of the diodes are fed to an amplifier circuit and converted into digital signals and evaluated by a further electronic circuit. Both circuits are not shown for simplification. Diffraction grating 14 and diode row 15 are cemented to or in a thick-walled glass housing 16 , as is the light guide 13 , which is designed as a row at the light outlet in the glass housing 16 , in order to achieve a slit-shaped radiation onto the diffraction grating 14 . The monolithic design of the spectral device 12 and the rigid connection of the device 12 and the measuring head 1 with the device base plate 2 lead to a stable structure without moving parts, freedom from wear, high reliability and permanent optical quality. In addition, it is achieved that the device is always in a ready-to-measure position due to the fact that its base plate 2 with the measuring opening 4 of the measuring head 1 integrated therein, as a result of which the movement sequence required for measuring, as mentioned, is reduced to a simple parallel displacement of the device to the measuring surface is. At the same time, the desired cost-effective construction has been achieved, which also results in a particularly compact and lightweight construction of the device and thus its sensitive displaceability.

Fig. 4 shows a section through the measuring head 1 with the inner light guide channel 17 , the measuring light lamp 18 , the illumination optics 19 and the light guide 13 of the spectral monolithic device 12th The light guide 13 is directed at an angle of 45 ° onto the measuring surface 7 , which results in the standardized 0 ° / 45 ° measuring geometry. At the entrance of the light guide 13 there is a rod lens 20 for focusing on the measuring surface 7 and a correction filter 21 with which, for example, undesired infrared light can be prevented. A photodiode 22 with a correction filter 23 is directed to the measuring light lamp 18 for brightness control. In conjunction with an electronic circuit, the brightness of the measuring light is kept constant. The arrangement of the spectral monolithic device 12 in the housing 3 separately from the measuring head 1 (see FIG. 3) enables the compact construction of a fixed measuring head without moving parts and the desired ease of use.

Claims (6)

1. Spectral hand-held measuring device for remission measurements on colored sheets and test forms, consisting of a device housing ( 3 ) with device base plate ( 2 ), a measuring head ( 1 ) with measuring light lamp ( 18 ) for generating the measuring light and with means for collecting the from the measuring surface ( 7 ) remitted light, an optoelectronic device ( 12 ) which is operatively connected to the measuring head ( 1 ) for spectral decomposition and evaluation of the remitted light and electronics for the digital processing of the measuring signals, characterized in that the measuring port ( 4 ) Part ( 5 ) laterally from the housing ( 3 ) protruding measuring head ( 1 ) and the spectral, monolithic device ( 12 ) formed from a diffraction grating ( 14 ) and a diode array ( 15 ) are connected by a light guide ( 13 ) and the Measuring head ( 1 ) and the spectral device ( 12 ) on the device base plate ( 2 ) are fixed, and the measuring opening ( 4 ) of the measuring head ( 1 ) in the plane ( 7 ) of the support surface ( 2 ') of the device base plate ( 2 ) is arranged. 2. Spectral hand-held instrument according to claim 1, characterized in that the apparatus base plate (2) is provided with at least three support side, these parallel to the support plane (7) holding the spacer elements (6). 3. Spectral hand-held measuring device according to claim 1 or 2, characterized in that the light guide ( 13 ) of the spectral monolithic device ( 12 ) in the measuring head ( 1 ) is directed at 45 ° to the measuring opening ( 4 ). 4. Spectral hand-held measuring device according to one of claims 1 to 3, characterized in that on the light entry side of the light guide ( 13 ) leading to the spectral monolithic device ( 12 ) a rod lens ( 20 ) and one of the rod lens ( 20 ) are arranged in front of a correction filter ( 21 ) . 5. Spectral hand-held measuring device according to one of claims 1 to 4, characterized in that a photodiode ( 22 ) and a correction filter ( 23 ) for regulating the brightness of the measuring light lamp ( 18 ) are arranged in the measuring head ( 1 ). 6. Spectral hand-held measuring device according to one of claims 1 to 5, characterized in that the part ( 5 ) of the measuring head ( 1 ) projecting from the housing ( 3 ) is designed in the form of a cone which tapers down to a substantially measuring opening size.