JP2506165B2 - Side printing device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial field of application] The present invention relates to characters and symbols such as manufacturer name, product type name, frame number, manufacturing date, manufacturing lot number, etc. at the edge of a color photographic material such as a color photographic film ( The present invention relates to a side printing apparatus used for printing a mark).

[Conventional technology]

In the process of manufacturing a photographic film, a mark is printed near the photographic film (between the perforation and the edge portion). This printing is called side printing, and is performed by a side printing device in which a large number of LEDs are arranged at right angles to the running direction of the film. Since characters of this print are printed on the film by the light of the LED, if one of the LEDs becomes abnormal, the printed character becomes unreadable.

In order to solve this problem, in the side print device described in Japanese Patent Application Laid-Open No. 58-219543, all LEDs are momentarily made to emit light all at once, and the entire current at that time is passed through one resistor. , The voltage fluctuation was measured and the LED abnormality was detected.

[Problems to be Solved by the Invention]

However, with the conventional side printing device described above,
In order to detect the abnormality of the LED, all the LEDs are made to emit light at the same time and the measurement is performed. Therefore, there is a problem that it cannot be performed when the film is attached to the side print device. Therefore, in order to detect the abnormality of the LED when the film is attached, there is a problem that the mechanism for shielding the film from the light of the LED is required and the device becomes complicated. Also, all LE
The LEDs are activated all at once to detect LED abnormalities.
When the number of LEDs increases, there is also a problem that the detection accuracy for an abnormality of one LED deteriorates.

[Object of the Invention]

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a side printing device that can check whether each LED is operating normally at the time of printing and that has improved LED detection accuracy.

[Means for solving the problem]

In order to achieve the above-mentioned object, a side print apparatus of the present invention is a light emission command means for outputting a light emission command signal to each of a plurality of light emitting elements that irradiate light for burning a latent image such as a character on an edge portion of a photosensitive material. And a light emission detection means for detecting the light emission state of each light emitting element based on the current flowing through each light emitting element and outputting a light emission confirmation signal for each light emitting element, and the light emission command signal and the light emission confirmation signal corresponding thereto. And a determination means for determining whether or not they match with each other.

[Action]

According to the above configuration, each light emitting element to which the light emission command signal is output from the light emission command means emits light. When the light emitting element emits light, the light emission detecting means detects the light emitting state of each light emitting element based on the current flowing through each light emitting element, and outputs a light emission confirmation signal to the determining means. The determination means compares the light emission command signal with the corresponding light emission confirmation signal to determine whether or not they match.

〔Example〕

In FIG. 4 showing the printing state of the side printing apparatus of the present invention, the film 2 is conveyed in close contact with the outer periphery of the roll 3 at a predetermined speed in the direction indicated by the arrow. A printing head 4 is provided above the roll 3, and a light source unit 5 is provided above the printing head 4. Seven LEDs 6a to 6g, which emit visible light, are provided at both ends of the light source unit 5, respectively.
Are arranged in the running direction and in the vertical direction. One end of the fiber cables 7a to 7g is connected to the seven LEDs 6a to 6g, and the other one of the fiber cables 7a to 7g is connected.
The ends are gathered in a line at both ends of the printing head 4.
Then, according to the light emission pulse of the controller described later,
When the LEDs 6a to 6g emit light, the light from the LEDs 6a to 6g is applied to the ends of the film 2 by the fiber cables 7a to 7g. Each time the film 2 is transferred by a certain distance, a predetermined number of times N
By only emitting light, one character represented by 7 × N pixels can be recorded as a latent image on the edge portion of the color film 2.

1 and 2 show the LE of the side printing apparatus of the present invention.
1 shows an example of a D emission control circuit and various pulse waveforms used in this emission control circuit. This light emission control circuit is provided with seven light emitting circuits 10a to 10g, as indicated by broken lines in the figure. Since the light emitting circuits 10a to 10g have the same configuration, the light emitting circuit 10a will be described below. This light emitting circuit 10a includes an _LED 6a connected to the anode side of the power supply line 9 of the potential V _LED , a resistor 11 connected to the cathode side of the LED 6a, and a resistor 12 connected in parallel to the LED 6a and the resistor 11. Become. A detection point 13 for detecting a potential is set at the opposite end of the resistor 11 connected to the LED 6a. Also,
The resistor 12 fixes the potential of the detection point 13 when the LED 6a is turned off to stabilize the operation of the analog comparator 14 described later, and when the LED 6a is disconnected, a minute current flowing through the resistor 6 is based on the drive amplifier 15 described later. It produces a cumulative effect.

An output terminal of a drive amplifier 15 composed of a transistor is connected to the detection point 13, and the drive amplifier 15 outputs a high level (hereinafter referred to as "H") from the controller 20 at t ₀ to t ₃ seconds. ) Is driven by the light emission pulse 30. The drive amplifier 15 becomes conductive after a lapse of a certain turn-on time, and a current is passed through the LED 6a to cause it to emit light. The input terminal of the analog comparator 14 is connected to the detection point 13,
The other input terminal of 14 is connected to a power supply line 16 to which a reference potential V _ref is applied. Then, the analog comparator 14 compares the potential of the detection point 13 with the reference potential V _ref , the LED 6a emits light after t ₁ second, and when the potential of the detection point 13 becomes lower than the reference potential V _ref, from the output terminal thereof. The light emission confirmation pulse 31a is output. The light emission confirmation pulse 31a becomes "H" at t ₁ second, and becomes low level at t ₄ second (hereinafter, "L").
It becomes). Although a transistor is used for the drive amplifier 15, a transistor array, a MOS ・ FET, a J
-Either FET may be used.

The output terminal of the analog comparator 14 is connected to the digital comparator 21 connected to the controller 20. The digital comparator 21 compares a plurality of light emission pulses 30 with light emission confirmation pulses 31a corresponding to the respective light emission pulses 30, and when the pattern of the light emission pulse 30 and the pattern of the light emission confirmation pulse 31a match. Outputs a coincidence output signal 32a of "H" as shown in FIG. This coincidence output signal 32a is t ₀ , t ₃ of the light emission pulse 30.
It becomes a low level (hereinafter, referred to as “L”) at the pulse edge at the time of second, and returns to “H” at the pulse edge at the time of t ₁ and t ₄ seconds of the light emission confirmation pulse 31a.

The digital comparator 21 includes an inverter 23 and t ₀ , t ₃
The monostable multivibrator 22 that operates at the pulse edge of the coincidence output signal 32a at the time of second is connected. When activated, the monostable multivibrator 22 outputs an "L" monostable output pulse 33 and returns to a stable state at t ₂ and t ₅ seconds. The output terminals of the inverter 23 and the monostable multivibrator 22 are connected to the latch circuit 24, respectively. When the coincidence output signal 32a does not return to "H" by the recovery time of the monostable multivibrator 22, the latch circuit 24 operates at the pulse edge of the monostable output pulse 33 at t ₂ and t ₅ seconds, The result of inversion of the coincidence output signal 32a is latched, and the LED light emission abnormality signal 34 is output from the output terminal. Latch circuit 2
A display device 25 driven by the LED light emission abnormality signal 34 is connected to 4.

The operation of the side printing apparatus thus configured will be described with reference to FIGS. 1, 2 and 4. When the roll 3 rotates and the film 2 is fed by a fixed amount, the controller 20 outputs a light emission pulse 30 to the drive amplifier 15 and the digital comparator 21 according to the input light emission pattern. The drive amplifier 15 driven by the light emission pulse 30 is turned on after ₁ second from t to emit the light from the LED 6a, and the light emitted from the LED 6a is guided to the fiber cable 7a and is irradiated to the film 2, so that the edge of the film 2 is hidden. Form an image.

When the potential of the detection point 13 drops at the same time when the LED 6a emits light after t ₁ second, the analog comparator 14 outputs a light emission confirmation pulse 31 to the digital comparator 21. When the pattern of the light emission pulse 30 matches the pattern of the light emission confirmation pulse, the digital comparator 21 causes the plurality of light emission pulses 30 and the plurality of light emission confirmation pulses 31a corresponding to the light emission pulse 30.
The coincidence output signal 32a based on the above is output to the latch circuit 24 via the monostable multivibrator 22 and the inverter 23. The monostable multivibrator 22 to which the coincidence output signal 32a is input outputs the monostable output pulse 33 to the latch circuit 24. By the way, in FIG. 2, before the monostable output pulse 33 returns from "L" to "H", the coincidence output signal 32a
Is "H", the latch circuit 24 does not output the LED light emission abnormality signal 34 to the display device 25.

When the LED 6a is abnormal, for example, a disconnection occurs, the current flowing through the drive amplifier 15 is only a minute current flowing through the resistor 12, so that the base accumulation effect occurs in the drive amplifier 15,
The turn-off time of the drive amplifier 15 becomes longer. Therefore, the light emission confirmation pulse output from the analog comparator 14
31b becomes "L" from "H" when t ₆ seconds as shown in Figure 3. The light emitting confirmation pulse 31b is coincident output signal 32b which is the digital comparator 21 input and output becomes "H" from "L" when t ₆ seconds. Therefore, when the coincidence output signal 32b is "L", the monostable output pulse 33 is "H".
become. The latch circuit 24 is driven by the pulse edge of the monostable output pulse 33 at time t ₅ seconds, and outputs the LED light emission abnormality signal 34b at time t ₅
Outputs to the display device 25 in seconds. And this
When the LED light emission abnormality signal 34b is output, the display device 25 displays the LED6
Display the anomaly of a. Therefore, in the side printing apparatus of the present invention, when printing on the film 2, each LED 6
It becomes possible to detect abnormalities of a to 6g. Also,
Since the analog comparator 14 is provided for each of the LEDs 6a to 6g, the abnormality can be detected with high accuracy even if the number of LEDs is increased.

FIG. 5 shows a second embodiment of the present invention. In this embodiment, a test timing generator 36 is used instead of the monostable multivibrator 22 described above. One end of the inspection timing generator 36 is connected to the controller 20.
, And the other end is connected to the input terminal of the latch circuit 24. The inspection timing generator 36 is driven by the light emission timing pulse from the controller 20, and outputs the latch timing pulse to the latch circuit 24. The other input terminal of the latch circuit 24 is connected to the digital comparator 21 via the inverter 23.

The latch circuit 24 detects the abnormality of the LED 6a by comparing the latch timing pulse from the inspection timing generator 36 with the time when the coincidence output signal 32a from the digital comparator 21 changes from "L" to "H". And the latch circuit 24
When detects an abnormality, the display device 25 is operated to display the abnormality of the LED 6a. If the inspection timing generator 36 is replaced with a monostable multivibrator, not only an abnormality when the LED 6a emits light but also an abnormality that emits light accidentally due to a short circuit of the drive amplifier when the LED 6a is turned off can be detected.

FIG. 6 shows a third embodiment of the present invention. In this embodiment, two detection points 4 are provided at both ends of the resistor 11 of the first embodiment.
0, 41 are provided, and at this detection point 40, an analog comparator 42 that outputs a signal when the potential becomes lower than the reference potential V _ref ,
Further, an analog comparator 43 that outputs a signal when the potential becomes lower than the reference potential V _ref is connected to the detection point 41. An output cutoff signal generator 44 is connected to the output terminal of the analog comparator 42, and an output breaker 45 that operates by the signal from the output cutoff signal generator 44 is connected to the output terminal of the analog comparator 43. .

In the embodiment configured in this manner, when the LED 6a normally emits light, the potential of the detection point 40 remains higher than the reference potential V _ref , so that the analog comparator 42 does not operate.
Therefore, the analog comparator 43 can output the light emission confirmation pulse 31a to the digital comparator 21 without being blocked by the output breaker 45.

Further, when the LED 6a becomes abnormal, the potential of the detection point 40 becomes lower than the reference potential V _ref , and the analog comparator
42 operates and outputs a signal to the output cutoff signal generator 44,
Activate this. When the output cutoff signal generator 44 operates and the cutoff signal is output to the output breaker 45, the light emission confirmation pulse 31a from the analog comparator 43 is output to the output breaker 4
It is cut off by 5 and cannot be output to the digital comparator 21. Therefore, when the light emission confirmation pulse 31a is not output, it can be confirmed that the LED 6a has an abnormality. Therefore, the light emission confirmation pulse output from the analog comparator 43 is the light emission confirmation pulse 31b of the first embodiment.
Since the monostable output pulse 33 does not have a time width like, the rough monostable output pulse 33 is sufficient.

FIG. 7 shows a fourth embodiment of the present invention, in which one drive amplifier 15 can emit a plurality of LEDs 47, 48. By doing so, the circuit of the third embodiment can be simply expanded.

In addition, in the above-mentioned embodiment, the light emission confirmation of the LED was performed by catching the change in the potential of the detection point caused by the current flowing through the LED, but the photo sensor is arranged in the vicinity of the LED and the light emission state of the LED is detected by the photo sensor. Also, the pattern may be confirmed.

〔The invention's effect〕

As described above in detail, according to the side print device of the present invention, a light emission command signal is output to each of a plurality of light emitting elements that emit light for printing characters or the like as a latent image on a traveling belt-shaped photosensitive material. Light emission command means, light emission detection means for individually detecting the light emission state of each light emitting element which emits light by the light emission command signal from the light emission command means, and outputting a light emission confirmation signal, the light emission command signal and the light emission command signal corresponding thereto. Since the light emission confirmation signal is compared with each other and a judgment means for judging whether or not they coincide with each other is provided, when the latent image such as characters is recorded on the photosensitive material, the judgment means causes abnormality of the light emitting element. Can be detected accurately and at the same time as light emission.

[Brief description of drawings]

FIG. 1 is a light emission control circuit diagram of a first embodiment of a side print device of the present invention. 2 and 3 are timing charts of various pulses output by the light emission control circuit shown in FIG. FIG. 4 is an explanatory diagram showing a printing state of the side printing apparatus of the present invention. FIG. 5 is a diagram showing a main part of a control circuit according to the second embodiment of the present invention. FIG. 6 is a diagram showing a main part of a control circuit according to the third embodiment of the present invention. FIG. 7 is a diagram showing a main part of a control circuit according to the fourth embodiment of the present invention. 2 …… Films 6a to 6g …… LED 14 …… Analog comparator 20 …… Controller 21 …… Digital comparator 25 …… Display device 42,43 …… Analog comparator 47,48 …… LED.

Claims (1)

(57) [Claims] 1. An edge portion of a traveling belt-shaped photosensitive material,
In a side-printing device for irradiating light from a plurality of light emitting elements to record characters and the like as a latent image, a light emission command means for outputting a light emission command signal to each of the plurality of light emitting elements, and a current flowing through each light emitting element. Based on the above, the light emission state of each light emitting element is detected, and the light emission detection means that outputs a light emission confirmation signal for each light emitting element is compared with the light emission command signal and the corresponding light emission confirmation signal. A side printing apparatus, comprising: a determination unit that determines whether or not the side printing apparatus is present.