DE3048704C2 - Photosensitive material processing device - Google Patents

Description

The invention relates to a processing device for photosensitive material, in particular a roller copier with a transport device for tape-shaped copying material, containing a light barrier for sensing the presence of the photosensitive material, which has a light emitter and a light receiver which is largely outside the sensitivity range of the material Radiation area work, the light emitter reducing the radiation exposure for the photosensitive Material only emits radiation from time to time.

Photoelectric barriers are common in processing devices to, for. B. during the threading phase of the photosensitive Detect material when the leading edge of the tape has exceeded a certain point has and z. B. pivotable insertion aids such as flaps, etc. can be pivoted away. Such flaps go z. B. from the DT-AS 44 960, but there are the magnets for Operation of the flaps controlled by microswitches operated by the paper tape. The light barriers for this purpose have the advantage that there is no mechanical contact with the copy material that occurs under Print exposure.

The use of light barriers, however, has the problem that the emitter and receiver of the measuring light have to work in a wavelength range in which the copy material is practically not sensitive Difficulties are encountered in meeting this requirement, particularly in the case of highly sensitive color material with several sensitivity ranges and when the material remains in the scanning position for a long time, because then undesired pre-exposure of the material can occur.

An electrophotographic copier for processing coated material is known from US Pat
Furthermore, from the magazine "Electronic Rundschau" No. 8/1972 known light-emitting diodes (LED) can be used in pulse mode. This happens because of the temperature dependence of the efficiency of the LED, so that in continuous operation with insufficient heat dissipation a reduction in the light output would occur. Application of this arrangement to processing devices for photosensitive material does not result

The object of the invention is to further reduce the radiation exposure for the light-sensitive material in the area of the light barrier, not only to reduce the time integral of the radiation dose by pulsed operation, but to be able to further lower the radiation dose required for the switching process.
This object is achieved by the invention described in claim 1.

The reduction of the harmful amount of radiation is achieved by reducing the duration of the radiation to continuously following pulses, i.e. a small part of the total time, while adapting the evaluation circuit to the pulse-shaped signals of the receiver achieves their conversion into a standing potential until between two sampling pulses a change in the passage of light between emitter and receiver occurs. Further details and advantages of the invention emerge from the dependent claims in connection with the description of two exemplary embodiments, which are explained in detail below with reference to figures. It shows
F i g. 1 a circuit diagram of a pulse-controlled light barrier,

2 shows a pulse diagram for the light barrier according to FIG. 1 and

F i g. 3 shows a block diagram of a light barrier operated with an oscillator.

In Fig. 1 is with 1 a tape of photosensitive material, e.g. B. a tape of color copier material in roll form referred to, which is fed through a roll copier. A couple of this is shown of drive rollers 2, 3 lead a pair of guide plates 4,5 to their contact gap, so that an in The beginning of the strip 1, which is advanced from left to right in the figure, initially between the metal sheets 4, 5 is guided into the nip 2, 3 and is then further conveyed by the rollers. The lower of the guide plates 5 is pivotable about an axis 6, for. B. by means of an electromagnet, not shown, so Jaß it can be brought into a position shown in dashed lines, so that from below a pictorial Exposure can take place on the downward-facing photosensitive side of the copy material 1. the The movement of the sheet 5 acting as a flap is controlled by a device arranged behind the rollers 2, 3 Light barrier with a light emitting di-

ode 6 (LED) and a receiver 7, a phototransistor, in such a way that when the tape reception passes through the flap 5 is pivoted downwards by the light barrier.

The drive device by means of the rollers 2, 3 and the introduction plates 4, 5 is only one of several Examples of using light barriers in processing equipment for photosensitive material can find. They can also be used to control the length of supply loops or to control them are used by drive rollers in gluing devices for films and the like that have not yet been developed.

According to FIG. 1, the electrical circuit for the light barrier 6, 7 is designed as follows known astable flip-flop with two gates 8 and 9 lying one behind the other are between these a resistor 10 and a diode 11 lying in series with a resistor 12, while connected to these a capacitor 13 connected to the output of gate 9 is connected in parallel by appropriate dimensioning of the resistors and the capacitor, the frequency is admitted so that the sampling frequency for the purpose of The light barrier is sufficient and a small pulse duty factor roughly according to the curve in FIG. 2a is achieved. At the exit the flip-flop is connected to a further gate 14 as an inverter, which has a switching transistor 15 in the circuit of the LED 6 controls the LED 6 preferably transmits in the infrared range, so that the radiation exposure for a copy material sensitized in the range of visible light not too large anyway is

A line 16 is connected to the output of the gate 9 and is connected to the trigger input 17t / of a flip-flop 17. The preparation input 17a of the trigger 17 is connected to the output of the photoreceiver 7 via a gate 18, while the second input 176 of the flip-flop 17 is connected to ground. The output 17c of the flip-flop is at the input of a switching transistor 19, which is wired with suitable resistors and makes the output signal of the flip-flop high impedance. At the output 20 of the switching transistor 19, z. B. the signal for controlling the magnet of the flap 5 can be derived.

The signal curve in the circuit according to FIG. 1 is in FIG. 2 shown. 2a shows the voltage on and the light output of the LED 6, which essentially follows the signal of the switching transistor 15, with a slight offset to the output signal of the phototransistor 7 according to FIG. 2b, while the signal curve at the output 17c of the flip-flop is shown in FIG. From this it can be seen that when a pulse in 2a meets a pulse at 2b for the first time due to the release of the light beam between 6 and 7, the flip-flop changes to the positive position, which it maintains as long as the falling, the trigger edge of the pulses in 2a coincides with a sampling signal of the receiver 7. If there is no pulse in 2b during the falling edge of the pulses in 2a, the flip-flop 17 returns to the output signal. This is the case when the luminous flux is interrupted between 6 and 7 ω

Since the pulses according to FIG. 2a can be very short, the exposure of the copy material to light is considerably reduced despite the constant intensity of the pulses. Nevertheless, the security of the recognition is fully preserved. The assignment of the signals between 2a and 2b is ensured because of the direct connection of the flip-flop 17 to the flip-flop.

Another embodiment of the invention is shown in FIG Fig. 3 described. Here the LED 6 'is connected to an oscillator 21 serving as a current source, the A phase-sensitive amplifier 23 controls via phase adjuster 22. The output signal of the light receiver "/ 'is also fed to the phase-sensitive amplifier 23 via an amplifier 24, which is, for example, a field-effect transistor FET be trained know. At its output is an inductance 25, resistor 26 and Capacitor 27 connected to the existing low-pass filter, which diverts noise and interference voltages to ground. Finally, a switching amplifier 28 is provided for sampling the potential at the capacitor 27, which in turn directly z. B. the magnet for moving the flap 5 in F i g. 1 could control.

The mode of operation of the circuit according to FIG. 3 is the following:

The oscillator circuit 21 controls the light emission of the diode 6 '; the resulting alternating light falls on the photo receiver of the light barrier. Whose amplified output signal comes to the FET 23. Die The FET is controlled via the phaser 22 in such a way that the phase position between the amplified Sampling signal and the drive signal of the FET is so that only the positive half-wave of the amplified Sampling signal reaches the low-pass filter 25, 26, 27 As a result, the capacitor charges up to the switching threshold of the amplifier 28, while interference and Noise components due to their statistically distributed phase position according to the time constant of the RC element average out. The dimensioning of the RC element must correspond to the required scanning speed the light barrier. The greater the time constant, the greater the inertia of the system, but the greater the sensitivity of the arrangement and the lower the light intensity of the diode 6 'can be selected.

Because of the possibility of precise phase adjustment between the received signal of the phototransistor T and the control of the FET 23, it is therefore possible to work with very low light intensities without any loss of detection reliability.

For this purpose 2 sheets of drawings

Claims (3)

Patent claims: 1. Processing device for light-sensitive material, in particular roller copier with a transport device for tape-shaped copying material, containing a light barrier for sensing the presence of the light-sensitive material, which contains a light emitter and a light receiver, which work in a radiation range lying largely outside the sensitivity range of the material, the Light emitter for reducing the radiation load for the light-sensitive material only emits radiation at times, characterized in that the light receiver (7, T) is connected to an evaluation device containing a flip-flop (17) which, by taking into account the pulses from the emitter (6, 6 ') acting on the power supply (8, 9; 21) generates a permanent display potential in such a way that the flip-flop can be reversed by pulses from the power supply, provided there is no pulse from the light receiver (7) 2. Processing device according to claim 1, characterized characterized in that the power supply of the emitter (6) has an astable trigger circuit (8, 9) contains a duty cycle 3. Processing device according to claim 1, characterized in that the power supply of the Emitter (6 ') contains an oscillator (21) which, via a phase adjuster (22), acts as an evaluation device Serving phase-sensitive rectifier for the signal of the light receiver, in particular one Field effect transistor (FET) (23) controls, to which a low pass (25,26,27) with RC element and with switching amplifier (28) for the capacitor voltage (27) is connected