DE1622484C3 - Device for measuring the optical reflectivity or the optical transmittance of a printed sample - Google Patents

Description

The invention relates to an apparatus for measuring optical reflectivity or optical Permeability of a moving carrier material, in particular a moving web, at regular intervals Intervals applied print pattern, with a stationary light source, with a stationary photoelectric Receiver, one after the other with the print pattern and the unprinted carrier material surfaces reflected or transmitted light is applied, and with one to the photoelectric Receiver connected evaluation circuit for generating a measurement signal from the difference between that of the print pattern and the unprinted areas in the exit of the photoelectric receiver evoked signals.

A device of this type is known (US-PS 29 69 016, DT-AS 11 31 427), the light source of which is continuous Emits light and its photoelectric cell from a rotatable, on a peripheral part an opening having aperture is surrounded, the rotation of which via the rotary movement of a pressure roller with the movement is coupled to the carrier web. The aperture is always then for the passage of the reflected light opened when a color test pattern specially applied to the carrier web for the measurement at the lighting point passes the light source. Such a device has due to the use of a continuous and therefore a relatively weak light source and limited photocell sensitivity especially with low reflectivity or low light transmittance of the pattern a relatively low sensitivity and accuracy. In addition, the achievable signal-to-noise ratio Left to be desired, unless the ambient light is effective through cumbersome shields is kept away from the photocell. It is also felt to be disadvantageous that the known device only for measuring color test samples specially applied to the carrier web for measurement, not against it is suitable for direct monitoring of the actual print pattern.

It is also known per se for color matching devices (DT-AS 10 44 443), an electrical discharge flash tube to be used to enable color matching under daylight-like light.

The invention is based on the object of the known device of the type described in the introduction to improve that a better signal-to-noise ratio is obtained and that arbitrarily designed Print patterns can be monitored immediately.

To solve this problem, it is proposed according to the invention that a pulsed light source be used as the light source with a screen arranged in front of it to limit the amount emitted by the pulsed light source Light beam provided on a compared to the extent of the print pattern small area is, and that a trigger circuit for triggering a short light pulse of high intensity at Occurrence of a print pattern or an unprinted carrier material surface is present.

The use of a pulsed light source has the advantage that it is repeated, relatively uniform light pulses of high intensity are generated. Short switch-on date due to short-term impulses and high peak luminosity, the total power requirement for the light source is greatly reduced and Heat dissipation problems are reduced to a minimum, while at the same time making them cheaper to use Solid-state photocells is made possible. In addition, a pulsed light source with high instantaneous Luminosity the unfavorable effects of the ambient light on the measurement accuracy by the large difference in brightness between normal ambient light and pulse lighting effectively eliminated. With the pulsed light source triggered according to the illumination of the carrier material can reliably measure the reflection or transmission characteristics even of fast moving objects be measured.

According to an advantageous embodiment of the invention, the trigger pulses for the pulsed light source are derived from the rotational position of the printing roller that prints on the carrier material. It is also possible to derive the trigger pulses from reference marks located on the carrier material.
Advantageously, the sensitivity of the fo-

electrical receiver through a negative feedback circuit in inverse proportion to the amplitude of the unprinted carrier material surface influenced pulse changed.

The invention is explained in more detail below with reference to the drawing. It shows

F i g. 1 is a diagrammatic representation of the mode of operation of a synchronized pulsed light photometer for continuous measurement of the reflectivity of repeated, by means of a high-speed printing press generated print pattern,

F i g. 2 shows a simplified diagrammatic representation of a photocell detector for generating the trigger pulses for the pulsed light source by direct scanning the printed carrier web,

F i g. 3 a preferred field delimitation for the in F i g. 1 shown pulsed light optics,

F i g. 4 is an electrical block diagram for the in FIG. 1 illustrated pulsed light photometer.

In Fig. 1 is a simplified illustration of a pulsed light photometer with which the color reflection characteristics of a print pattern 100 which is repeated at regular intervals and which is printed by an offset print roller 110 onto a continuously running carrier web 105 can be measured. Each repetition of the print pattern 100 is illuminated by a synchronized light pulse which reaches the pattern from the pulsed light source 10 via the condenser lens 106, the diaphragm 99 and the field lens 111. The light pulse reflected from each print pattern 100 is concentrated by the lens 108 via a suitable color filter 112 onto the photoelectric receiver 140.

In a preferred embodiment of the in FIG. 1, the photoelectric receiver 140 and the pulsed light source 10 are mounted in a common head 107 which is mounted so that it can be displaced perpendicular to the direction of travel of the printed carrier web. As shown, the optics are arranged so that the lenses have a common focal point on the printed surface along the transverse axes AA .

The axis AA lies at a predetermined distance X from the offset roller 110 . In order to ensure an exact synchronization of the pulsed light source during the transition of each print pattern 100 over the transverse axis AA , a magnetic transmitter is provided, which consists of the coils 116/4 and 116ß and the permanent magnets 117Λ 117ß mounted on the disc 119 , the disc 119 is driven by the platen shaft 120. The magnets 117/1 and 117 ß are preferably attached to the disk 119 with movable clamping devices, so that the time or phase position of the in the transmitter coils 116/4 and 116 £? generated trigger pulses can be easily adjusted. This allows the angular adjustment of the magnets 117 A and 117ßim relation to the drive shaft 120 and the printing pattern on the printing roller 110 so that the desired displacement is reached to trigger the lamp 10, when the print pattern 100 by a distance X from the central axis of the pressure roller 110 moved away. To simplify the drawing, the engraved ink roller known per se has been omitted for the printing roller UO.

. For practical reasons, the diaphragm 99 is preferably disc-shaped (as shown in FIG. 3) and has an opening in the center which is surrounded by a dark ring with reduced light transmission. The outer diameter of the field delimitation image 99 / should preferably be approximately 25 mm, that of the light spot in the middle approximately half. The lens 108 is arranged with respect to its focal point and its orientation in such a way that it images the field delimitation 141 / within the bright center spot of the image 99 / (cf. FIG. 3). To delimit the field 141 / , a diaphragm 141 is arranged in front of the photoelectric receiver 140.

The correct stroboscopic phase position of the image 99 / in relation to the entire image area can easily be achieved by turning the transmitter coil 116.4 or 1165 by hand in relation to the magnets 117Λ or 117ß. As indicated above, the entire head 107 is mounted on a suitable transverse bearing so that the operator can select the reflection of any point on the printed surface by visually setting up the boundary image while the transducer coil is being adjusted and can be measured by the operator when passing through the axis AA .

As in Fig. 4, synchronization pulses generated by the transmitter coils 116Λ and 116S are fed to a bistable multivibrator 150. The spool 116/4 is mechanically phased in relation to the platen in such a way that it generates a flash trigger pulse when an unprinted (e.g. white) area appears at AA. Conversely, coil 116S is phased to generate a trigger when the desired printed area appears at AA. Accordingly, the flip-flop circuit 150 is switched and switched over by the corresponding trigger pulses of the coils 116/4 and 116ß. The output pulses of flip-flop 150 go over diode 161 and a differentiator 162 to the pulse light shutter 160. The flash lamp power supply 165 is suitably energized by a delayed output pulse of the trigger 160 while the solenoid coil of the synchronous switch 170 and the synchronous modulator 175 amplified by the in the amplifier 166, instantaneous pulses of the flip-flop 150 are excited.

The output signals of the photoelectric receiver 140, which correspond to the light pulses reflected alternately from the unprinted (for example white) and the printed carrier material surfaces, are developed via the potentiometer 171 . The switching arm A of the relay switch 170 is switched so that it switches the input of the amplifier 176 alternately to the wiper and to the upper terminal of the potentiometer 171. During operation, the potentiometer's slider is set so that the "color-free" pulse 180 and the "color pulse" 181 have the same amplitude if the color layer has the desired thickness or density. In the preferred embodiment, pulses 180 and 181 are separately integrated and compared by difference comparator 185. The individual integration circuits can have conventional FIC integration circuits which have relatively large time constants compared to the pulse duration, so that the output signals obtained represent the integrated or total energy in each of the input pulses 180, 181. The difference or error signal is fed to the writer 190 and, if desired, can also serve to excite a servo-controlled inking roller so that it automatically corrects errors or fluctuations in the ink thickness. The error signal can also

a servo amplifier (not shown) with motor control for automatic adjustment of the potentiometer 171, so that the output error signal is continuously held at a zero value. The reflectance or transmission value of the print sample can then easily be read off a scale indicating the position of the potentiometer 171.

The DC supply voltage for the photoelectric receiver 140 is expediently provided by a current gate negative feedback circuit controlled. In the embodiment shown in Figure 4, the sensitivity of the photoelectric receiver only controls the "color-free" pulse amplitude in the opposite ratio between the wiper of potentiometer 171 and the earth, and the percentage difference between the ratio of the reflection values in the printed and in the unprinted state is measured and recorded by the writer 190.

Accordingly, "color-free" pulses are synchronized through the ß-contacts of switch 170 to the peak detector 195 applied, which generates a variable DC control voltage that the photocell 140 is supplied through the DC control tube 191.

As noted above, the potentiometer 171 wiper is normally set to accommodate the Output error signal eo is zero at a desired ink layer thickness. The scale of the potentiometer 171 can expediently be calibrated in such a way that the percentage difference between the reflection of the Print pattern and that of the unprinted or white area can be read, and that the ratio between the difference between the reflectance values and the reference white reflectance by the writer 190 is recorded. Thus, fluctuations in the reflectance value of the unprinted area will occur with each Measurement effectively switched off and only percentage fluctuations in the actual paint layer thickness registered.

In Fig. 2 shows another arrangement for generating synchronizing pulses, which is a photocell 200 with a lens 201 which is arranged to print the outer edge of the web 105 along Reference marks 205 scanned. The pulses of the photocell 200 amplified in the amplifier 209 are expediently fed to a variable delay circuit 210, which is an advantageous means to adjust the phasing of the stroboscopic light so that each part of the print pattern can be easily illuminated. When printing on individual cardboard or separate pieces, you can get through Scanning the leading edges of each individual piece generates reference stimuli advantageous for control the flash lamp.

For this purpose 2 sheets of drawings

Claims (4)

Patent claims: 1. Device for measuring the optical reflectivity or the optical permeability of a print pattern applied at regular intervals on a moving carrier material, in particular a moving web, with a stationary light source, with a stationary photoelectric receiver, the one after the other with the print pattern and the unprinted Carrier material surfaces reflected or transmitted light is acted upon, and with an evaluation circuit connected to the photoelectric receiver for generating a measurement signal from the difference between the signals caused by the print pattern and the unprinted surfaces in the output of the photoelectric receiver, characterized in that a pulsed light source is used as the light source (10) is provided with a screen (99) arranged in front of it to restrict the light beam emitted by the pulsed light source (10) to a small area compared to the extent of the print pattern (100) and that a trigger circuit (116a, 1166,150,160, 161, 162, 165; 200, 201, 210) for triggering a short light pulse of high intensity when a print pattern (100) or an unprinted carrier material surface occurs . 2. Apparatus according to claim 1, characterized in that the trigger pulses for the pulsed light source (10) can be derived from the rotational position of a printing roller (110) which prints on the carrier material (105) . 3. Apparatus according to claim 1, characterized in that the trigger pulses for the pulsed light source (10) can be derived from reference marks (205) located on the carrier material (105). 4. Apparatus according to one of claims 1 to 3, characterized in that the sensitivity of the photoelectric receiver (140) can be changed by a negative feedback circuit (B, 195, 196) in inverse proportion to the amplitude of the pulse influenced by the unprinted surface of the carrier material.