CS217571B1 - Connections for automatic protection of a CCTV camera against strong light sources - Google Patents

Abstract

The connection for automatic camera protection allows it to be controlled from multiple independent control workstations. During the short measurement period, there is no irreversible damage to the picture tube. The connection can be used especially in environments with strong light sources such as liquid metal, lighting fixtures, etc. It can also serve as a remotely or manually controlled switch for a network of CCTV cameras with multiple independent workstations, each on a separate monitor. The connection is modular and can be modified as desired.

Description

The wiring for automatic camera protection allows it to be controlled from multiple independent control workstations. There is no irreversible damage to the image tube within a short measurement time.

The connection can be used especially in environments with strong light sources such as liquid metal, lighting fixtures, etc. It can also serve as a remote or manually operated switch of the CCTV network with multiple independent workstations always on a separate monitor. The wiring is modular and arbitrarily modified.

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BACKGROUND OF THE INVENTION The invention relates to a circuit for automatic protection of a CCTV camera against sources of strong light radiation in operations where a source of strong light radiation is brought into the camera using multiple independent control stations. Strong light radiation causes damage and ultimately complete destruction of the CCTV video tubes.

It is known to protect a CCTV camera by illuminating the captured scene until the brightness of the captured scene is approximately the same as the brightness of the light sources in the camera frame, and the CCTV lens obscures to a suitable size.

The disadvantage of this method of protection is that the scene being scanned must be illuminated up to high illumination values, up to thousands of Lx, and in a large scene a large number of luminaires as well as a considerable power input are required. Good results can only be obtained if the scenes are small enough and the radiation source is not very strong.

Another known method is to protect the CCTV camera by including a suitable optical filter in front of the lens and to illuminate the scene to a value of several hundred Lx. The brightness of the scanned scene and the brightness of the glowing objects behind the optical filter are again the same.

The disadvantage of this method of protection is again the fact that a large power input is required to illuminate a large scanned scene. Another disadvantage is that the downstream filter only protects the CCTV camera from light of certain wavelengths. If a glowing source emitting light of other wavelengths is engaged, this protection is ineffective.

Another known method of protecting CCTV cameras is to install a suitable photoelectric sensor that responds to the presence of glowing objects in the camera's frame by causing the camera to be obscured.

The disadvantage of this method of protection is that the photoelectric sensor is not able to react to small glowing objects that also damage the CCTV camera, as measured at the CCTV installation site, these sources cause a change in illumination which is compared to normal illumination (weather, dimming) up to several orders of magnitude smaller. The sensor is located at the installation site of the CCTV camera.

Another well-known way to protect a CCTV camera is by wiring, which automatically protects it so that it is always obscured and the choice is screened for about 1 minute. and after this time, the camera will automatically screen.

The disadvantage of this method of protection is that it protects the camera, but only when using a single control and observation station.

These drawbacks are eliminated by the circuitry for the automatic protection of a CCTV camera against sources of strong light radiation for a plurality of independent control workstations according to the invention, which consists of a first, second to nth dial, a first, second to nth slot, first, second to n -th switchboard, camera with control unit and first, second to nth monitor.

The start output of the first dial is connected to the start input of the first controller, the start output of the second dial is connected to the start input of the second controller, and the start output of the nth dial is connected to the start input of the nth controller. connected to the setting input of the first switching block, the setting output of the second dialing block is coupled to the setting input of the second switching block, and the setting output of the nth dial is coupled to the setting input of the nth switching block, the opening output of the first automat is connected to the opening input of the first switch block, the opening output of the second automat is connected to the opening input of the second switch block, and the opening output of the nth machine is connected to the opening input of the nth switch, at the same time the closing output of the first automat is connected to the closing m output of the second automaton and with the closing output of the nth automaton and also with the closing input of the first switching block, wherein the control gating output of the first automat is connected to the controlling gating input of the first switching block; block and the controlling gating output of the n-th automaton is connected to the controlling gating input of the n-th switching block, similarly the image gating output of the first automaton is connected to the image gating input of the first switching block; block and the image gating output of the n-th automaton is connected to the image gating input of the n-th switching block, while the control output of the first switching block is connected to the closing input of the second the switching block and the control output of the second switching block is connected to the closing input of the n-th switching block, wherein the control output of the nth switching block is connected to the control input of the camera to the control unit; the switching output of the second switching block and the video input of the nth switching block, wherein the bus output of the first switching block is connected to the video input of the first monitor, the bus output of the second switching block is connected to the video input of the second monitor and the bus output ri217571

The th switch block is coupled to the video input of the n th monitor.

The advantage of the wiring according to the invention is that it automatically protects the CCTV camera from being damaged by strong light sources at any number of independent control workstations, so that the camera is constantly obscured and the camera is deflected for about 50 seconds when selected at any workstation. the camera is automatically blanked. When selecting a camera from another workplace, the entire cycle is repeated. If the camera is selected while observing from another location, the total observation time will be increased by 50 seconds from the time of re-selection, and after 50 seconds after the first location is selected, the monitor at the first location is disconnected but the camera is not obscured. The camera will be screened after 50 seconds from the second job. Thus, the camera is screened somewhat longer than in the previously mentioned examples. The time interval can be freely changed, however, the time of about 1 minute for observation of the image in dispatching practice is sufficient. If the source of strong light radiation is in front of the lens of the screened camera, it cannot be damaged and if the source is in front of the lens of the screen camera, irreversible damage to the video tube of the CCTV camera will not be irreversibly damaged. Another advantage is that the CCTV camera works with a scene illumination of around 100 Lx, which means considerable savings in the electrical energy required for lighting. The camera retains good resolution for much longer than cameras without this protection.

An example of a circuit for automatic protection of a CCTV camera against strong light sources for multiple independent control workstations according to the invention is shown in the drawing where a block diagram of the circuitry for automatic protection of a CCTV camera against strong light sources for multiple independent control workstations is shown.

The first control panel 1 consists of the push buttons and the summation circuit, and its start output 14 is connected to the start input 15 of the first controller 4, which consists of passive and active elements, similarly the start output 16 of the second control panel 2 is connected to the start input 17 and the start output 18 of the nth counter of option 3 is connected to the start input 13 of the nth machine 6. The controllers automatically control the operation of the other blocks of the entire circuit. The setting output 20 of the first option board 1 is connected to the setting input 21 of the first switching block 7, similarly the setting output 22 of the second option board 2 is connected to the setting input 23 of the second switching block 8 The switching blocks consist of active and passive elements and are used for gated switching of the control signals and gated switching of the video signal of the CCTV camera. The opening output 26 of the first automaton 4 is connected to the opening input 27 of the first switching block 7, also the opening output 28 of the second automaton 5 is connected to the opening input 29 of the second switching block 8, and the opening output 36 of the nth automat is connected to the opening input 31n. The closing output 32 of the first automaton 4, the closing output 34 of the second automaton 5 and the closing output 36 of the nth automaton 6 are connected to the closing input 33 of the first switching block 7. Further, the control output 50 of the first switching block 7 is connected to the closing input 35 of the second switching block 8, the control output 51 of the second switching block 8 is connected to the closing input 37 of the nth switching block

The control gate output 38 of the first controller 4 is connected to the control gate input 39 of the first switching block 7, the control gate output 40 of the second controller 5 is connected to the control gate input 41 of the first switching block 8, and Similarly, the image gating output 44 of the first switch 4 is coupled to the image gating input 45 of the first switch block 7, the image gating output 46 of the second switch 5 is coupled to the image gating input 47 of the second switch. The control output 52 of the nth switch block 9 is coupled to the camera control input 83 with the control unit 10. The video output 53 of the camera with the control unit 10 is sp not only with the video input 54 of the first switch block 7, with the video input 55 of the second switch block 8, and with the video input 56 of the nth switch block 9. The bus output 57 of the first switch block 7 is coupled to the video input 60 of the first monitor 11; the switching block 8 is connected to the video input 61 of the second monitor 12, and finally the bus output 59 of the nth switching block 9 is connected to the video input 62 of the nth monitor 13.

The wiring works as follows. The operator of any control station chooses the moment of observation, such as operating the first dial1, by pressing the button on the first dial1. The signal from the setting output 20 of the first dial1 passes to the setting input 21 of the first switching block 7 and sets it to the active position . At the same time, the first option 1 panel produces a start pulse that passes from the start input 14 of the first option 1 panel to the start input.

7 5 71 of the first automaton 4. At this moment, an impulse appears on the control gating output 38 of the first automaton 4, which brings them to the controlling gating input 39 of the first switching block 7. The first switching block 7 is set by the button , the remaining switching blocks are still in the passive position. Therefore, in the first switching block 7, the opening input 27 of the first switching block 7 is in the unlocked state and the closing input 33 of the first switching block 7 is blocked. The other switching blocks are in a passive state and therefore, for example, the opening input 31 of the nth switching block 9 is blocked and the closing input 37 of the nth switching block 9 is unlocked. Simultaneously with the arrival of a pulse on the control output 38 of the first controller 4, a pulse also appears on the opening output 28 of the first controller 4, which is shorter and is sufficient to open the aperture on the camera with the control unit 10. block 7, then passes to the control output 50 of the first switching block 7, which is in the active state, from which the opening pulse arrives at the closing input 35 of the second switching block 8, which is in the passive state, and 8 until it finally reaches the closing input 37 of the nth switch block 9. This is also in a passive state and therefore passes the opening pulse to the control output 52 of the nth switch block 9. Finally, the opening pulse reaches the control input 63 of the camera with the control unit 10 where it causes a deflection. At the video output 53 of the camera with the control unit 10 an image signal appears which is applied to the video inputs of all switch blocks. At the moment of the pulse termination at the opening output 26 of the first automaton 4, a pulse appears on the image gating output 44 of the first automaton 4, which is applied to the image gating input 45 of the first switching block 7. This is active. The first signaling block 7 with the bus output 57 of the first switching block 7 and the video signal thus arrives at the video input 60 of the first monitor 11. The operator at this point observes the selected camera image for the duration of the video gating pulse from the first automaton. . After the picture observation time, about 1 minute, the pulse on the image gating output 44 of the first controller 4 and the control gating output 38 of the first controller 4 ends, so that the video input 54 of the first switch block 7 and the bus output 57 of the first switch block 7 and the image on the first monitor 11 disappears. Also, the opening input 27 of the first switching block 7 is interrupted with the control output 50 of the first switching block 7, thereby closing the closing input 33 of the first switching block 7 with the control output 50 of the first switching block 7. At this point The controller 4 detects an impulse that reaches the closing input 33 of the first switching block 7, which is already in a passive state and therefore the signal passes to the control output 30 of the first switching block 7, further to the closing output 35 of the second switching block 8. to the control output 51 of the second switch block 8, and finally to the closing input 37 of the nth switch block 9, and further to the control output 52 of the nth switch block 9, further to the camera control input 63 with the control unit 10 where closing the aperture. This completes the cycle and repeats when the camera is selected again. A special case of the function occurs when, at any point in the cycle currently described, the camera is also selected at another control station, e.g. the nth station. The operator selects the moment of observation by pressing the buttons on the nth dial of option 3. The signal from the setup output 24 of the nth dial of option 3 together with the signal on the control gating output 42 of the nth automat 6 which is triggered by the signal from the start output 18 n- The 3rd input of the nth switch 6 sets the nth switch 9 to the active position so that the opening input 31 of the nth switch 9 is connected to the control output 52 of the nth switch 9 to open the closing input 37 of the nth switch block 9 with the control output 52 of the nth switch block 9. At the same time a pulse is generated at the opening output 30 of the nth switch 6. This pulse reaches the opening input 31 of the nth switch 9 from there to the control output 52 of the nth switch block 9 and then the camera control input 63 with the control unit 10 where it could cause t aperture opening, however, since the camera is already tilted, the image is observed at another workstation, it does not affect it. Upon completion of this pulse, a pulse is generated at the video gating output 48 of the n-th machine 6, which is coupled to the image gating input 49 of the n-th switching block 9 and here interconnects the video input 56 of the n-th switching block 9 and the bus output 59. The nth switch block 9 and the video signal from the video output 53 of the camera with the control unit 10 thus reaches the video input 62 of the nth monitor 13. From this point on, the nth operator also observes the image of the selected camera with the control unit 10 as the first workplace. Suppose the observation cycle at the first site has just ended. As previously described, the image is disconnected from the video input 60 of the first monitor 11, but the signal from the closing output 32 of the first automaton 4 in this case only reaches the closing input 37 of the nth automaton 9 which is currently in active state and therefore this pulse does not pass and cannot cause the camera to be obscured by the control unit 10, as this is still being observed by the nth site. Upon completion of the observation cycle of the nth workstation, the pulse is terminated at the image gating output 48 of the n-th machine 6 and at the control gating output 42 of the n th machine 6, which results in the image input 56 of the n-th switching block 9 output 59 of the n-th switching block 9, and the image on the n-tether monitor 13 disappears. At the same time, the opening input 31 of the nth switch block 9 is opened with the control output S2 of the nth switch block 9 and the closing input 37 of the nth switch block 9 is connected to this output. This means that all switching levels are now

Claims (1)

SUBJECT Circuit for automatic protection of CCTV camera against strong light sources consisting of first dial, second dial up to nth dial, first slot, second slot to nth slot, first toggle block, second toggle block to n- and a camera with a control unit, further from a first monitor, a second monitor to a n-th monitor, characterized in that the start output (14) of the first dial counter (i) is connected to the start input (15) of the first controller (4). ) and at the same time the setting output (20) of the first dial (1) is connected to the setting input (21) of the first switching block (7), the start output (16) of the second dial of the dial (2) is connected to the start input (17) of the second (3) is connected to the start input (19) of the nth machine (6), at the same time the setting output (22) The second output block (8) is connected to the setting input (23) of the second switching block (8), and the setting output (24) of the nth dial (3) is connected to the setting input (25) of the nth switching block (9) wherein the closing output (32) of the first automat (4), the closing output (34) of the second automat (5) and the closing output (36) of the nth automat (6) are connected to the closing input (33) of the first switching block (7) further, the control output (50) of the first switch block (7) is connected to the closing input (35) of the second switch block (8), the control output (51) of the second switch block (8) is connected to the closing input (37) of the nth Ky in a passive state. At this point, pulses are generated at the closing output 36 of the n-th machine 6; this pulse passes sequentially through the closing input 33 and the control output 50 of the first switching block 7, then through the closing input 33 and the control output 51 of the second switching block 8, also through the closing input 37 and the control output 52 of the nth switch 9 to the control input 63 cameras with a control unit 10 to cause screening; this is the end of the cycle, and no workplace now sees the image. In particular, the invention is used to protect a CCTV camera in environments where a strong light source is engaged by multiple independent observation workstations, in an application where it is not necessary to view the image continuously, but only for a limited time at an arbitrary time. BACKGROUND OF THE INVENTION, at the same time, the opening output (26) of the first automat (4) is connected to the opening input (27) of the first switching block (7), the opening output (28) of the second automat (5) is connected to the opening input ( 29) of the second switching block (8), even the opening output (30) of the nth automat (6) is connected to the opening input (31) of the nth switching unit (9), the control gating output (38) of the first automat ( 4) is connected to the control gating input (39) of the first switching block (7), the control gating output (40) of the second automat (5) is connected to the control gating input (41) of the second switching block (8) and the control gating output (42) ) of the n-th automat (6) is connected to the control gating input (43) of the n-th switch block (9), while the video gating output (44) of the first automat (4) is connected to the image gating input (45) of the first switch block 7, the image gating output (46) of the second automat (5) is connected to the image gating input (47) of the second switching block (8) and also the image gating output (48) of the nth automat (6) is connected to the image the gate output (49) of the nth switch block (9), the control output (52) of the nth switch block (9) being connected to the camera control input (63) of the control unit (10), and the video output (53) the camera with the control unit (10) is connected to the video input (54) of the first switching block (7), the video input (55) of the second switching block (8) and the video input (56) of the nth switching block (9) the bus output (57) of the first switch block (7) is connected to the video input (60) of the first monitor (11), the bus output (58) of the second switch block (8) is connected to the video input (61) of the second monitor (12) and nth switch block output (59) (59) 9) is coupled to the video input (62) of the n-th monitor (13).