RU1778744C - Film indicating device in camera feeding mechanism - Google Patents

Abstract

The invention relates to photography and can be used in cameras, the shutter of which is controlled by electric current pulses, mainly in frame aerial cameras. The aim of the invention is to increase the accuracy of the display with automatic detection of the duration of processing of film. The invention allows to solve the following problems: significantly improve the quality of aerial photography materials by accurately determining the length of the exposed aerial film and automatically determining the optimal processing time; to save on expenditure and time spent on chemical-photographic processing of the film, and to further automate the process of azrophotography. The device contains a photoelectric W ё

Description

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frequency sensors 1.2, amplifiers-foomizers 3.4, frequency divider 5, five electronic keys, delay line, pulse generator, electronic switch, indicating unit 14, counting unit 15, decoder 16, signaling unit 27 and block arithmetic operations 26, pulse shaper 17, circuits OR 18.19. comparison circuits 20.21, frame adjusters 22.23, trigger 24, pulse counter 25, development cuvette clock adjuster 29, and display information and control panels 28.30 for the aerial camera. 1 ill.

The invention relates to photography, and in particular to structural elements of cameras, and can be used in cameras whose shutter operation is controlled by electric current pulses, and mainly in frame aerial cameras.

It is known that, depending on the design of the aerial camera, the meter (meter) of exposed (unexposed) zerofilms or the counters of exposed (unexposed) frames are used to determine the flow rate (residue) of aerial film. The existing designs of such counters do not allow the length of the exposed aerial film to be determined with sufficient accuracy.

In connection with the increased requirements for saving expensive aerial film, the question arose of a more accurate determination of its length, which can be exposed during aerial photography. This length will be equal to the length of the aerial film charged into the cassette (cassette part) of the aerial camera, with the exception of the length of the aerial film used to charge the receiving (reeling) coil, to test the operation of the aerial camera during preliminary and preflight preparations, before flying to the aerial photograph - during post-flight inspection, as well as imprinting of sensitometric wedges at the beginning and end of aerial photos and on test development during chemical-photographic processing. The length of the aerial film consumed in this case is difficult to determine. Therefore, after charging the cassette and testing the operation of the aerial camera, as a rule, the actual length of the remaining unexposed aerial film is unknown. When determining the length of the remaining unexposed aerial film, two circumstances must be taken into account that may occur in HS practice.

1. If, when charging a cassette, the rakord will not be completely rewound to the receiving reel, and the counter of exposed frames

set to zero, the length of the unexposed aerial film will be determined with a constant error equal to the length of the unwound record. In this case, it is possible to expose the rewound portion of the leader at the beginning of aerial photography instead of aerial film. At the end of photographing, the frame counter will show that exposure of the aerial film is complete, although, in fact, the aerial film is not fully exposed. This may lead to the fact that at the beginning of aerial photography, some of the photographed objects will not be displayed on the aerial film.

2. If, in addition to the record, a portion of unexposed aerial film is rewound to the receiving coil and the frame counter is set to zero, then the length of unexposed aerial film will be determined with a constant error equal to the length of aerial film rewound to the receiving coil. At the end of aerial photography, the frame counter will show that the aerial film is not exposed entirely, although in fact the exposure of the aerial film will be completed. In this case, exposure of the leader connected to the second end of the aerial film is possible. This can lead to the fact that at the end of aerial photographing, some of the photographed objects will not appear on the aerial film.

Knowing the length of expended aerial film during cassette charging would allow us to determine the actual length of unexposed aerial film, and therefore the number of frames that can be exposed during aerial photography, and, in particular, the corresponding corrections to the previously calculated aerial photography parameters.

Among the many factors affecting the quality of aerial photographs, chemical photographic processing of exposed aerial films occupies a prominent place.

The main processes of chemical photographic processing are the development, fixation and final washing. Under normal conditions of chemical photographic processing, the influence of each of the processes on the quality of aerial photography materials is related to its duration. Duration of processes that is less than optimal leads to the appearance of difficult to repair or practically unremovable defects, and the duration of processes that is longer than optimal also causes the appearance of various kinds of difficult to eliminate defects, unproductive consumption of chemical-photographic solutions, water, electric energy, forces, and means and increased processing time.

The duration of this or that stage of the process of chemical-photographic processing, first of all, depends on the length of the processed aerial film. The actual length of the aerial film to be chemically photographed is difficult to determine if it is only part of the nominal length of the charged aerial film, or if the aerial film is loaded into the cassette without a record.

Currently, the determination of the duration of TPR in minutes is carried out, as a rule, according to empirical formulas:

-when processing on manual reamers for rewinding type aerial material

Tpr.cuv + 0.20 (); (1)

-when processing on semi-automatic rewinding devices for rewinding type aerial photos

Tnp + 0.17 (L-28), (2)

where t.cuv is the duration of the manifestation of one frame in the cuvette, min;

L is the length of the developed aerial film, m.

The duration of fixation of aerial films Tf in minutes is determined by the formulas given in the guidelines for processing aerial films:

-when using manual rewinding devices

TF 0.36 (L - 5) + 3: (3)

-when using rewinding type semi-automatic washing devices

TF - 0.36 (L - 28) + 3. (4)

and the duration of the final rinse of the Aerofilm Top in minutes is determined by the following formulas:

-when using manual rewinding devices

Top 0.36 (L - 5) + 8; (5)

- using semi-automatic rewinding devices

5Top 0.36 (L - 28) + 8; (6)

where L is the length of the processed aerial film, m.

As can be seen from the above, the determination of the optimal duration 0 of the development time, fixation, and final washing requires knowledge of the cuvette development time (different for different types of aerial films), the type of measuring device, the length of the 5 aerial films being processed, the corresponding formulas, and the necessary calculations which leads to certain difficulties and additional time spent on chemical photographic processing. 0 Known devices for determining the length of unexposed aerial film using various counters. The most widely used devices using mechanical 5 meter counters, the main disadvantages of which are:

a) the dependence of the readings on the thickness of the aerial film charged into the cassette;

b) the accuracy of measurements is low;

0 c) the impossibility of remote monitoring.

Indirectly, the length of unexposed aerial film can be determined from the readings of electromechanical counters5 of unexposed frames, the main disadvantages of which are:

a) the accuracy of measurements is low;

b) the absence of an alarm about the limited remainder of the unexposed aero film;

c) the readings depend only on the operation of the shutter and are not dependent on the presence of aerial film and its condition in the tape drive;

5 g) the absence of an indicator of the length of the unexposed aorofotofilka.

Information on the movement (rewinding) of aerial film in the tape path is very significant.

0 aerial camera. Mechanical and electrical alarms are used to indicate normal rewind of aerial film. The most advanced technical solutions are electric signaling devices, representing various designs, making and breaking contacts when rewinding aerial photos. The main disadvantages of existing aerial rewind warning lights are:

a) lack of indication of the insufficient length of the rewound aerial film, leading to the superposition of the frame on the frame when it is exposed;

b) insufficient information about the breakage (termination) or termination of the rewinding of azrofotofilm (seizing).

In case of malfunctioning of the tape path leading to rewind of aerial film with the superposition of the frame on the frame, illusions of normal operation of the aerial camera are created. This leads to unproductive expenditure of expensive aerial film, funds, time and effort for its chemical-photographic processing and, ultimately, to failure to fulfill the assignment and contractual obligations, since the resulting aerial photography materials are not of practical value because of their Low quality. In addition, during breakage (seizing) or even after exposure of the entire aerial film, the normal operation of the aerial camera is created, since in their existing designs the photo shutter and frame counter continue to work, and the rewind alarm lamp will light up with every pulse coming from the control panel of the aerial camera. The operation of the photo shutter from electrical impulses coming from the aerophotopleics control panel in the cassette, as well as when rewinding it with the frame overlaid on the frame, leads to premature wear of the shutter mechanism and other details, which significantly reduces the life of the aerial camera.

The closest in technical essence to the proposed invention (its prototype) is a device according to USSR copyright certificate No. 1278786, published in 1987. It includes the following elements: photoelectric sensor, amplifier-shaper, frequency divider, three electronic keys, amplifier-shaper, divider frequencies, three electronic keys, a delay circuit, a pulse generator, an electronic switch, counting and indication blocks, two matching circuits, a frame encoder with encoders and a decoder.

- The elements and communications of this device allow only the frames to calculate the consumption of exposed and remaining unexposed aerial film. This leads to the inherent disadvantages of this device, the main of which are:

a) the inability to determine the actual length of the remaining unexposed aerial film;

b) the inability to determine 5 the length of the aerial film spent unproductively (imprinting sensitometric wedges, before charging, cassette charging, etc.);

c) the inability to determine 0 the actual length of the aerial film,

taken into account during chemical photographic processing;

d) the inability to automatically determine the duration of development, fixation, and final washing of the aropofilm to be chemically photographed;

e) automatic shutdown of the aerial camera after exposure to a predetermined number of frames, which is not always advisable.

The aim of the invention is to increase the accuracy of indications with automatic detection of the duration of the film processing.

The goal is achieved in that the output of the first photoelectric sensor is connected to the input of the first amplifier-former, the first output of which is connected to the input

0 delay line and the first input of the fourth electronic key, the second output is with the first input of the frequency divider, the first output of which is connected to the input of the first electronic key and the first input of the first OR circuit, the second output is with the first input of the counting block, the output of the first OR circuit is sequentially connected to the input of the pulse generator and the second input of the counting unit, the first output of which is sequentially connected to the inputs of the pulse former, the second OR circuit, the second input of the frequency divider, the second output of the counting unit a first input of block decoders, yield

5 of the delay line is connected to the third input of the counting unit, the second output of the pulse shaper is connected to the first inputs of the electronic switch and the display unit and the second input of the first OR circuit,

0 the output of the decoder unit is connected to the second input of the display unit and the first inputs of the first and second comparison circuits, the second inputs of which are connected to the outputs of the first and second frame adjusters respectively, the output of the first comparison circuit is connected in series with the input of the second electronic key and the first input of the signaling unit, The OUTPUT of the second comparison circuit is sequentially connected to the input of the third electronic key

and the second input of the signaling unit, the output of the second photoelectric sensor is connected to the input of the second amplifier-former, the first output of which is connected in series with the inputs of the fourth electronic key, pulse counter and the second inputs of decoder units and arithmetic operations, the second output is connected in series with trigger inputs, moreover the electronic key, by the control panel of the aerial camera and the second input of the electronic switch, the second output of the fifth electronic key is connected to the third input of the unit Single alarm output the displayed selection information console connected to the third input of the indication unit, the output of the first electronic switch is connected to the third input of the electronic switch, a first output connected to a fourth input of the indication unit, and the second output - with an electromagnet aerial camera shutter.

The difference between the proposed device and the prototype is that an additional photoelectric sensor, a second amplifier-driver, a trigger, a pulse counter, two electronic keys, arithmetic units, alarms and decoders, a display panel for the displayed information, a delay line, a pulse shaper, two OR schemes and a cuvette development time master.

The use of new elements and connections gives the proposed device new properties that increase the accuracy of the display by determining the actual length of the exposed or the remainder of the unexposed aerial film, automatically determining the duration of its development, fixing and final washing, as well as turning off the aerial camera after exposure of the entire aerial film.

Improving the accuracy of the aerial film indication in the tape path of the aerial camera is carried out by determining the actual length of the exposed or the remainder of the unexposed aerial film through the connections of another photoelectric sensor, a second amplifier-former, an electrode switch, a pulse counter and a decoder that determine the length of the exposed aerial photographs immediately after passing the gluing of the record with the aerial film.

Determination of development, fixation and final rinse time

Aerial films are provided due to the additional introduction of a cuvette development time, an arithmetic unit, decoders and their connections with a pulse counter and an indication unit into the device.

Structural diagram of the proposed device is presented in the drawing. On it, numbers indicate:

0 1.2 - the first and second photoelectric sensors, respectively, 3.4 - the first and second amplifiers-shapers, respectively, 5 - frequency divider, 6-10 - first, second, third, fourth and fifth

5 electronic keys, respectively, 11 delay lines, 12 - pulse generator, 13 - electronic switch, 14 - display unit, 15 - counting block, 16 - decoder block, 17 - pulse shaper shovels, 18.19 - first and second circuits OR, respectively, 20,21 are the first and second comparison schemes, respectively, 22,23 are the first and second frame managers, respectively, 24 is a trigger, 25 is a counter

5 pulses, 26 - arithmetic unit, 27 - signaling unit, 28 - display panel for selecting displayed information, 29 - cuvette development time dial, 30 - aerial control unit.

0 First Photoelectric Sensor 1

Designed to generate electrical signals when rewinding aerial film.

The second photoelectric sensor 2 serves to generate electrical signals5 during the passage of gluing the record with aerial film.

The first driver amplifier 3 is designed to generate rectangular pulses of the required amplitude from the signals coming from the output of the first photoelectric sensor 1.

The second driver amplifier 4 serves to amplify the signals coming from the output of the second photoelectric sensor 5 to 2 to a level that enables the trigger 24 and the fourth electronic switch 9.

Frequency divider 5 is designed to form one pulse from ten

0 pulses from the output of the first amplifier-former 3

The first electronic key 6 is used to receive a logical signal 1 upon receipt of a pulse from the output of the divider 5

5 of the frequency and feeding it to the first input of the electronic switch 13 and then to the display unit 14

The second electronic key 7 is designed to turn on the orange signaling unit 27 for signaling a limited frame remaining of unexposed aerial film.

The third electronic key 8 serves to turn on the red LED in the signaling unit 27, indicating that the planned number of frames is exposed.

The fourth electronic key 9 is designed to ensure the passage of pulses from the output of the first amplifier - driver 3 to the pulse counter 25 after passing the gluing of the record with aerial film at its beginning.

The fifth electronic key 10 serves to enable the audible alarm in the alarm unit 27 when the aerial film is fully exposed, i.e. after passing the second sticking of the aerial film record, and applying a signal to the control panel 30 to turn off the aerial camera.

The delay line 11 is intended to delay the pulses coming from the output of the first amplifier-former 3 for a while relative to the pulses coming from the output of the pulse generator 12, in order to avoid the undefined state of the reversible counter located in the counting unit 15.

A pulse generator 12 is used to generate pulses enabling the operation of a reversible counter.

An electronic switch 13 is used to control the trigger electromagnet of the aperture of the aerial camera.

The indicating unit 14 serves to indicate the duration of the chemical photographic processing of the aerial film and to monitor the state of the aerial film in the tape drive of the camera. It has two LEDs and four indicators. The green LED indicates normal rewind of the aerial film, and the red LED indicates malfunctions in the tape path of the aerial camera (rewind aerial film with the overlay on the frame; breakage or jamming of aerial film). One of the indicators is used to indicate the total length of the exposed aerial film, the other to indicate the duration of the development of aropofilms, the third and fourth to indicate the fixation and washing of the aerial film, respectively.

The counting unit 15 is for setting the total and counting the remaining number of unexposed frames. It contains a reversible counter, a pulse generator that serves to set the total number of frames to be

exposure, and a counter indicator indicating the current value of the remaining unexposed frames.

The decoder unit 16 serves to accommodate five decoders. The first decoder serves to translate the binary code of the signal from the output of the counting unit 15 into a decimal code and feed it to the inputs of the first and second comparison circuits 20.21, respectively. Second decoder

it is intended to translate the binary code of the aerial film development time, it comes from the output of the arithmetic unit 26, and the decimal code to indicate it in the display unit 14. Third

the decoder serves to translate the binary code of the aerial film fixation time coming from the output of the arithmetic unit 26 to a decimal code to indicate it in the display unit 14, The fourth decoder interrogates to translate the binary code of the final washing time coming from the output of the arithmetic unit 26 to decimal code dp indication of it in the block

14 indications. The fifth decoder is designed to convert the binary code of the length of spent aerial film into the decimal meter indication code in the indication unit 14.

The pulse generator 17 is intended to generate a pulse from a positive potential at the output of the reversible counter in case of malfunctions in the tape drive path of the aerial camera.

The first OR circuit 18 serves to control the operation of the pulse generator 12.

The second OR circuit 19 is for controlling the operation of the frequency divider 5. The first and second comparison schemes 20.21 respectively serve to select decimal numbers in accordance with the data set on the first and second adjusters 22.23 frames, respectively.

The first frame adjuster 22 is designed to set a number corresponding to the number of frames, upon reaching which an orange LED will light up in the signaling unit 27, signaling the remainder of a limited number of unexposed frames.

The second frame adjuster 23 serves to set the number corresponding to the number of frames, upon reaching which the red LED will light up in the alarm unit 27 and an audible siren will turn on, indicating that the planned number of frames has been exposed, and aerial photography with this aerial camera must be stopped.

The trigger 24 is designed to turn on the fifth electronic key 10 when passing the second gluing aerial film with a record.

The pulse counter 25 is used to count the number of pulses coming from the output of the first amplifier-former 3, and to supply a binary code signal proportional to the length of the spent aerial film to the inputs of the arithmetic unit 26 and the decoder unit 16.

Block 26 of arithmetic operations is intended to solve equations (1-6) for determining the duration of development, fixing and final washing of aerial film and supplying signals proportional to these values in binary code to the input of block 16 decoders and then to the second, third and fourth decoders, respectively .

The signaling unit 27 serves to turn on the light and sound alarms informing the operator about the limited remaining unexposed aerial film, about exposing a predetermined number of frames, about exposing the whole aerial film and that the aerial camera is turned off. LEDs are placed in the signaling unit, one of which signals a limited number of unexposed frames, the other indicates that the planned number of frames is exposed, the third indicates that the entire aerial film is exposed. In the same block there is a generator for changing the duration of the glow of the LEDs, an audible siren that signals the exposure of the whole aerial film, and an LED that indicates that the aerial camera is turned off.

The display information selection panel 28 is designed to provide the ability to display the necessary information (the length of the exposed aerial film, the duration of development, etc.) in the display unit 14 at the request of the operator.

The cuvette development time setter 29 is used to set a number corresponding to the development time of one frame in the cuvette. Other parameters necessary for solving equations (1-6) and converting them into binary code are also set here. as well as a switch of the type of broaching device: Manual - Semi-automatic.

The control panel 30 is designed to control the operation and control of the aerial camera.

The first photoelectric sensor 1 consists of an optocoupler pair and a modulator, which is a disk with holes. The disk is rigidly connected to the axis of the measuring

roller. The diameter of the disk and the number of holes in it are selected so that when rewinding aerial film to a length equal to the size of one frame with an interframe gap, to the input of the divider 5

ten pulses were received. This number of pulses provides the simplest execution of the rest of the circuit.

Second Photoelectric Sensor 2

represents an optocoupler pair consisting of an infrared LED and a photodiode. When moving the cord between the elements of the optocoupler at the output of the photodiode, there will be no signal, because the leader material is opaque to infrared rays. At the moment of passing the gluing of the record with aerial film at the output of the photodiode, a signal will appear that will be fed to

the input of the second amplifier-shaper 4.

The remaining elements of the proposed device can be performed using standard microcircuits, transistors and switches:

- amplifier amplifiers, frequency divider, delay lines, pulse generator, blocks of decoders, counting and arithmetic operations, comparison circuits, trigger, pulse counter, OR circuit

and a pulse shaper is assembled using standard microcircuits of the appropriate types;

- electronic keys, electronic switch, display information selection panel, frame and cuvette development time adjusters can be performed using dependent switches;

- as indicators of the length of the exposed aerial film, the duration of its development, fixation and final washing, digital indicators of the ALS type can be used;

- a control panel is included with the aerial camera.

The above-described elements of the device in a static state have the following connections. The output of the first photoelectric sensor 1 is connected to the input of the first amplifier-former 3, the first output of which is connected to the input of the delay line 11 and the first input of the fourth electronic key 4, the second output is connected to the first input of the frequency divider 5, the first output of which is connected to the input of the first electronic key 6 and the first input of the first OR circuit 18, the second output with the first input of the counting unit 15, the input of the first OR circuit 18 is connected in series with the input of the pulse generator 12 and the second input of the counting unit 15, the first output of which therefore, connected to the inputs of the pulse shaper 17, the second circuit OR 19, the second input of the frequency divider 5, the second output of the counting unit 15 is connected to the first input of the decoder block 16, the output of the delay line 11 is connected to the third input of the counting block 15, the second output of the pulse shaper 17 is connected with the first inputs of the electronic switch 13 and the display unit 14 and the second input of the first OR circuit 18, the output of the decoder unit 16 is connected to the second input of the display unit 14 and the first inputs of the first and second comparison circuits 20, 21, the second inputs of which are connected to the outputs of the first setter 22 frames and the second setter 23 frames, respectively, the output of the first comparison circuit 20 is connected in series with the input of the second electronic key 7 and the first input of the signaling unit 27, the output of the second comparison circuit 21 is connected in series with the input of the third the key 8 of the electronic and the second input of the signaling unit 27, the output of the second photoelectric sensor 2 is connected to the input of the second amplifier-former 4, the first output of which is connected in series with the inputs of the fourth electric a key switch 9, a counter of 25 pulses and second inputs of the units 16 of the decoders and 26 arithmetic operations, the second output is connected in series with the inputs of the trigger 24, the fifth electronic key 10, the remote control 30 of the aerial camera and the second input of the electronic switch 13, the second output of the fifth the electronic key 10 is connected to the third input of the signaling unit 27, the output of the display information selection panel 28 is connected to the third input of the display unit 14, the output of the first electronic key 6 is connected to the third input of the switch 13 electronic, the first output of which is connected to the fourth input of the display unit 14, and the second output - with the shutter electromagnet of the aerial camera.

The operation of the proposed device is carried out as follows.

When pre-flight preparation of aerial equipment is carried out, a number corresponding to the duration of the development of one aerial film frame charged to the cassette (cassette part) of the aerial camera (this value is indicated on the label of the packaging box in which the aerial camera was stored) is set on the cuvette detection time detector 29. Depending on the type of wiring device planned for use in chemical-photographic processing of exposed aerial film, the type of work switch located on the front panel of the setter 29 of the cuvette for the development time is set to Manual or Semiautomatic.

At the frame counter located in the counting unit 15, a number is set corresponding to the number of frames that can be exposed by aerial photography.

A number corresponding to the number of unexposed frames is set at the frame master 23, upon reaching which a sound siren should turn on in the alarm unit 27. This number consists of the number of unexposed frames necessary for the test manifestation during chemical photographic processing of aerial film, imprinting of sensitometric wedges after discharging the cassette, and for testing the operation of the aerial camera during post-flight preparation.

On the frame master 22, a number corresponding to the number of frames is set, upon reaching which the LED in the signaling unit 27, informing about the limited remainder of the aerial film, which can still be exposed, will start to light.

When charging the cassette with aerial film inside the second photoelectric sensor 2, the initial moment will move the record. In this case, the signal will not be supplied to the electronic circuit; the readings of the length indicator of the exposed aerial film located in the display unit 14 will be zero.

When the aerial camera is turned on and the aerial film is normally rewound, pulses from the Larofotoapparat control panel (PU AFA) are fed through the electronic switch 13 to the shutter release electromagnet, which triggers the cassette's electric motor circuit, which winds the aerial film through the measuring roller. The rotation of the measuring roller is transmitted to a rigidly connected disk with holes modulating the light flux in the optoelectronic pair of the first photoelectric sensor 1. The signals generated in this case, the number of which is proportional to the length of the rewound aerial film, go to the input of the first amplifier-former 3, from the first output of the last to the first input of the fourth key 9 of the electronic and to the input of the delay line 1, from the second output to the first input of the divider 5 frequencies. After rewinding the record and passing gluing with aerial film at the output of the second photoelectric sensor 2, a signal is received which will be fed to the input of the second amplifier-former 4. The amplified signal from the first output of the second amplifier-former 4 will go to the second input of the fourth electronic switch 9, which It will open and provide the passage of pulses from the first output of the first amplifier-former 3 to the input of the counter 25 pulses. From the first output of the counter of 25 pulses, information on the length of the rewound aerial film in binary code will go to the input of the fifth decoder in the block 16 of decoders, from the output of which information in the decimal code will go to the input of the display unit 14 and then to the indicator of the length of the rewound windshield. From the same output of the pulse counter 25, the binary code signals will be fed to the second input of the arithmetic unit 26, to the first input of which signals in the binary code from the setter 29 of the development cuvette are received. After appropriate transformations, signals proportional to the duration of development, fixation, and final washing of the aerofilm, from the output of block 26 of arithmetic operations in binary code, the t-gathers of the second, third, and fourth decoders in block 16 of decoders are received. From the outputs of the same decoders, information in a decimal code about the duration of development, fixation and final washing will go to the second input of the display unit 14 and then to indicators of the duration of development, fixing and final washing of the aerofilm.

When aerial photography is performed to exclude the illumination of numerous indicators and LEDs, which distract the operator’s attention, the device uses a remote control28 to select the displayed information, by means of which this or that indicator is illuminated in the display unit 14 only at the request of the operator.

0 After rewinding the azofotofilm to a length equal to the size of one frame with an interframe gap, pulses from the outputs of the frequency divider 5 are fed to the input of the first electronic key 6 and the first

5 the input of the counting unit 15. The pulses from the output of the first electronic key 6 through the switch 13 electronic are fed to the non-raw input of the display unit 14, where the green LED starts to glow,

0 signaling normal rewind of aerial film in the tape path of the aerial camera. During normal re-filing of aerial film at the output of the reversible counter located in block 15

5 countable, the potential is 0th, because its inputs of Addition and Subtraction receive the same number of pulses from the outputs of the first amplifier-former 3 and the pulse generator 12. This amount

0 pulses are selected equal to ten. The choice of this amount is due to the simplicity of the design of the device. After ten pulses arrive at the input of the frequency divider 5 at its output,

5 pulse, which through the first circuit OR 18 will turn off the pulse generator 12. At the same time, the entire circuit of the device will return to its original state. The next cycle of work begins with the arrival of the next impulse

0 from the remote control 30 of the aerial camera. Each pulse coming from the first output of the frequency divider 5 to the input of the counting unit 15 reduces the number of unexposed frames by

5 unit, as indicated by the counter indicator located in this block.

From the output of the counting unit 15, information in binary code is fed to the input of the first decoder through the first input of block 16

0 decoders, and from the output of this decoder to the first inputs of the first and second comparison circuits 20,21, respectively.

When the number of unexposed frames reaches a value equal to the number

5 installed on the first frame master 22, the first comparison circuit 20 is triggered, the second electronic key 7 opens and the orange LED in the signaling unit 27 lights up to indicate a limited remainder of unexposed frames.

When the number of unexposed frames reaches a value equal to the number set on the second frame master 23, the second comparison circuit 21 will operate, the third electronic key 8 will open, and in the signaling unit 27 a red LED will light up, indicating that the planned number of frames is exposed, and aerial photography with this aerial camera must be stopped. Simultaneously with the start of the red LED, the second electronic key 7 will close, and in the signaling unit 27, the orange LED will stop illuminating, signaling a limited number of unexposed frames. If after that the aerial camera is not turned off, then exposure of the aerial film will continue until in the field of view of the second photoelectric sensor 2 a second gluing of the aerial film with a record is not visible. Then, at the output of the second photoelectric sensor 2, the signal disappears, the fourth electronic key 9 closes, the signals from the first output of the first amplifier-former 3 stop at the input of the pulse counter 25, thereby eliminating further calculation of the length of the exposed aerial film. At the same time, trigger 24 will open, providing the opening of the fifth electronic key 10, which closes the electrical circuits for the passage of signals to the control panel 30 to turn off the aerial camera from work and to the third input of the signaling unit 27, in which the LED, informing about exposure of a given number of frames, will stop and will start the red LED lights up to indicate that the camera is turned off. At the same time, an audible siren will turn on, indicating that the exposure of the aerial film has been completed.

If malfunctions are detected in the tape path of the aerial camera (rewind aerial film with the image superimposed on the frame; breaking it or seizing it), the number of pulses of less than ten will arrive through the delay line 11 through the delay line 11. After the difference in the number of pulses arriving at the inputs of the reversible counter is equal to three (for the reliability of the malfunction of the tape drive), a positive potential appears at its output. The pulse shaper 17 on the leading edge of this potential will generate a pulse that will close the electronic switch 13, which will provide an exception

the operation of the shutter, and therefore exposure of the aerial film, turns off the pulse generator 12, sets the frequency divider 5 to zero, and provides a glow in the display unit 14

0 red LED, indicating malfunctions in the tape path of the aerial camera. The first electronic key 6 is closed, and in the display unit 14, the LED will stop glowing

5 green, indicating normal rewind of aerial film.

After troubleshooting in the tape path, further aerial photography is necessary

0 press the button on the control panel of the aerial camera, which sets the circuit to its initial state.

The device provides for checking the operability of light and sound alarms5. Such verification is carried out when preparing aerial equipment for flight and, if necessary, in flight.

The proposed technical device compares favorably with the new

0 elements and links, the implementation of which allows to determine with greater accuracy the length of the exposed aerial film, and therefore the length of the remaining unexposed aerial film, as well as

5 to take into account the length of the aerial film spent on unproductive needs (cassette charging, imprinting of sensitometric wedges, etc.); more accurately determine the length of aerial film,

0 subject to chemical-photographic processing (it is especially important to know if only part of the aerial film is exposed); enables automatic determination of the duration of the manifestation,

5 fixing and final washing for various types of aerial films and various washing devices, and also ensures that the aerial camera is switched off after exposure of the whole aerial film.,

The achieved technical effects can significantly improve the quality of aerial photography materials by accurately determining the length of the exposed aerial film and, consequently, the optimal duration of development, fixation and final washing; to ensure the saving of chemicals, expensive aerial film, electrical energy and time spent on chemical photographic processing of aerial film; increase the life of the aerial camera by eliminating the shutter when the aerial film is rewound with the image overlay, a cliff or its seizing, as well as after exposing the entire aerial film, and further automate the aerial photography process.

The expected technical and economic effect of the proposed device can be judged at least on the basis of the example below.

We will evaluate only the means spent unproductively during aerial photography without the proposed device, without taking into account other values. Let aerial photography be carried out with an AFA-42/20 aerial camera charged with type 22 aerial film, 32x600cm in size. The flight duration of the aircraft is two hours. The length of the exposed aerial film was erroneously determined to be less than the actual length. When substituting an erroneously determined length in formulas (1-6), the durations of development, fixation and final washing are determined to be less than optimal. Therefore, after chemical-photographic processing of aerial film, low-quality materials will be obtained (low optical density, yellowness, etc.) even if the aerial film is correctly exposed. Due to the impossibility of eliminating the resulting defects, such material will not be accepted by the customer.

Overhead costs will consist of the cost of flight time and aerial film consumption during aerial photography, developer and fixer during chemical photographic processing. The table below shows these costs.

In fact, this amount will be much larger, since the above example did not take into account the aerial photography area, the salary of the flight crew and maintenance personnel, the depreciation of the aircraft, and much more, as well as the cost of water and electric energy spent during the chemical-photographic processing and drying of the aerial film . These unproductive expenses will increase even more when aerial photographs are used for spectrozonal and color aerial films, the cost of which and the chemicals used to process them are much higher than the cost of black and white aerial photographs. It is known that

aerial photography is carried out in clear weather, which sometimes has to be expected for a very long time. The waiting time increases the amount of expenses for the rental of an aircraft - 5 device. To reduce these costs, it is necessary that each departure for aerial photography and the resulting materials be of high quality. The proposed device is intended to contribute to this.

The device is designed to operate in low temperature conditions; provides remote indication and can be installed on existing cameras designed for aerial photography, without significant changes in their designs, as well as on various devices in which information is recorded on film or oscillographic paper, and during chemical photographic processing.

Claims (1)

SUMMARY OF THE INVENTION A film indicating device in a tape path of a camera comprising serially connected a first photoelectric sensor, a first driver-shaper, a frequency divider, a counting unit, a decoder and a display unit connected in series to the first 0 key and electronic switch, the first output of which is connected to the second input of the display unit, the second output is to the bus of the shutter solenoid, delay element, pulse generator, control unit, connected to the second input of the electronic switch, the first and second comparison blocks, the first inputs which are connected to the outputs of the first and second frame managers with By encoders, the second inputs are connected to the decoder output, and the outputs are connected to the inputs of the second and third keys, respectively, characterized in that, in order to increase the accuracy of the indication with the automatic determination of the duration of the film processing, a second photoelectric sensor and a second amplifier are connected in series - former, trigger, fourth key and signaling unit, the second and third inputs of which are connected to the outputs of the second and third keys, respectively, in series nye fifth key, the pulse counter and arithmetic 5 block, the output of which is connected to the second input of the decoder, the third input of which is connected to the output of the pulse counter, a cuvette development time sensor connected to the second input by the output arithmetic unit, pulse shaper and OR element, one input of which is connected to the input of the first key and the second output of the frequency divider, the other input is connected to the third input of the electronic switch, with the third input of the display unit and the first input of the pulse shaper, the second output of which is connected to the second input of the frequency divider, the output of the OR element is connected to the input a pulse generator, the output of which is connected to the second input of the counting unit, the third input of which is connected through a delay element to the second output of the first amplifier-former and one input of the first key, the other input of which is connected to another output of the second amplifier-former, and the other output of the fourth key connected to the input of the control unit. Total: 2,057.44