RU52226U1 - MONITORING DEVICE - Google Patents

Abstract

The utility model relates to surveillance systems and can be used in the manufacture of outdoor cameras designed to operate in low temperature conditions. The monitoring device comprises a protective casing and a power and control unit located inside it, a video camera with a lens and a heating element with a thermostat, electrically connected to the power and control unit, and the protective casing has two holes in the ends, one of which is intended for the video camera lens and is equipped with a protective glass, and the other is designed to accommodate the inputs and outputs of cables. The heating element is installed inside the camera body. The protective glass of the device is equipped with an additional heating element, electrically connected to the power supply and control unit. The device is additionally equipped with an LED emitter and a photodetector, each of which is electrically connected to the power supply and control unit, the photodetector being optically coupled to the LED emitter through the optical surface of the protective glass within the lens aperture, and the power supply and control unit further includes a light emitting power measuring unit for the LED emitter reflected from the optical surface of the protective glass, and the control circuit of the additional heating element.

Description

The utility model relates to surveillance and security tools and can be used for television surveillance of objects in a protected area.

A monitoring device is known (Certificate for Utility Model RU 13437, published on April 10, 2000, Bull. No. 10), the functional element of which is a television camera placed in a protective casing with high dust and moisture resistance. The casing has two holes in the ends, one of which is designed for the camera lens and is covered with transparent glass, and the other hole is used to accommodate the cable inlets and outlets. To maintain operability and ensure the normal functioning of the electronic circuits of this device at low ambient temperatures, the casing is equipped with a heater and thermostat.

The main disadvantage of this device is its high power consumption due to the high heat transfer of the housing body at low ambient temperatures. An additional disadvantage of this device is its low stealth, because non-optimal location of the heater inside the protective casing leads to inefficient heating of this casing, and, thereby, to an increase in the probability of detection of the device by a potential intruder of the protected area at night with

using night vision devices, thermal imagers or other thermal radiation detectors.

Closest to the proposed device and selected as a prototype is an improved surveillance device (Certificate for Utility Model RU 20599, published on November 10, 2001, Bull. No. 31) containing a protective casing and a power and control unit placed inside it, a video camera with a lens and a heating element with a thermostat, electrically connected to the power supply and control unit, and the protective casing has holes in the ends, one of which is intended for the camera lens and is equipped with a protective glass, and the other is designed EHO to accommodate inputs and outputs of the cables, the heating element with the thermostat is mounted on the upper surface of the camera, and between the lower surface of the camera housing and the housing is placed pad of thermally insulating material.

With a similar arrangement of the heater, the temperature of the housing of the protective casing is closer to the ambient temperature, however, a significant temperature difference is preserved, heat transfer and energy consumption remain high. These circumstances determine the large power consumption of the prototype in conditions of low ambient temperatures. In addition, there remains a high likelihood of detecting the fact of observation by thermal radiation of the protective casing of the prototype.

The task to which the proposed utility model is directed is to reduce power consumption when the device is operating in low ambient temperatures while reducing

the probability of detecting its functioning, in other words, to increase the stealth of observation.

The problem is solved by achieving a technical result, which consists in increasing the efficiency of the heater.

When implementing the proposed utility model, the indicated technical result is achieved by the fact that in the monitoring device containing a protective casing and a power and control unit located inside it, a video camera with a lens and a heating element with a thermostat, are electrically connected to the power and control unit, and the protective casing has two holes in the ends, one of which is intended for the lens of the video camera and is equipped with a protective glass, and the other is designed to accommodate the inputs and outputs of the cables, heating lement is installed inside the camcorder body.

In addition, a thermostat can also be installed inside the camera body.

In addition, the thermostat can be made in the form of a bimetallic plate.

In addition, the thermostat can be made in the form of a thermocouple.

In addition, the protective glass may be provided with an additional heating element electrically connected to the power supply and control unit. The presence of an additional heating element on the protective glass increases the reliability of the device in cases of adverse weather conditions, such as dew or precipitation in the form

rain and snow, a sharp drop in temperature at which fogging occurs and the transparency of the protective glass decreases.

In addition, the device can be additionally equipped with an LED emitter and a photodetector, each of which is electrically connected to the power supply and control unit, the photodetector being optically coupled to the LED emitter through the optical surface of the protective glass within the lens aperture, and the power supply and control unit further includes a measurement module power of the light flux of the LED emitter reflected from the optical surface of the protective glass, and the control circuit for additional heating lnym element.

In addition, the radiation wavelength of the specified LED emitter may be in the infrared range of the spectrum.

In addition, the power supply and control unit of the device can be additionally equipped with a module for generating pulsed electrical power for the LED emitter.

In addition, the inner surface of the protective casing may be coated with a layer of heat insulating material.

The essence of the utility model is illustrated by the drawing, which shows a diagram of the proposed monitoring device in the best performance. A video camera 1 with a lens 2 is placed in a protective casing 3, which has two holes at the ends. One hole is intended for the lens 2 of the video camera 1 and is provided with a protective glass 4, and the second hole is designed to accommodate the inputs and outputs of the cables 5 to the video camera 1 and to the inside

a protective casing 3 to the power supply and control unit 6. A heating element 7, for example, a thermistor, with a thermostat 8, made, for example, in the form of a thermocouple, which are electrically connected to the power and control unit 6, is installed inside the camera body 1; the protective glass 4 is equipped with an additional heating element 9. The device contains a transparency control system for the protective glass 4, consisting of an infrared LED emitter 10, for example, SFH 4350 manufactured by OSRAM and a photodetector 11, for example, a silicon photodiode PD 7K optically coupled to each other through the optical surface of the protective glass 4. An additional heating element 9, an LED emitter 10 and a photodetector 11 are electrically connected to a power supply and control unit 6, which is equipped with a pulsed electric power generation module for the LED emitter 10, a light flux power measurement module reflected from the optical surface of the protective glass 4 and the control circuit of the additional heating element 9. The protective casing 3 is additionally coated inside and a layer of heat insulating material 12, for example, polyurethane foam.

The device operates as follows. At low ambient temperatures (for example, at a temperature of -50 ° C and below), the electronic power and control circuits of the camcorder 1 do not ensure its normal functioning. To turn on the camcorder 1 according to the technical conditions of its operation, it is necessary to ensure the preliminary heating of electronic components. Low temperature alarm

values from the thermostat 8 (temperature sensor, made, for example, in the form of a bimetallic plate or thermocouple) enters the power supply and control unit 6, as a result of which the power supply and control unit 6 includes a heating circuit of the heating element 7. The heating element 7 heats the electronic components inside the housing video cameras 1. When the temperature rises to the operating value, the video camera 1 turns on, and the video signal from the video camera 1 enters the transmission line to the television monitor. The heating element 7 together with the thermostat 8 maintains the operating temperature inside the camera body 1. The placement of the heating element 7 inside the camera body 1 minimizes heat loss and improves the efficiency of the heating element 7, as well as reduces the energy consumption of the device as a whole. In turn, reducing the heat transfer of the casing 3 to the environment by reducing the volume of the heated space and the use of low thermal conductivity of the air inside the camera 1, reduces the likelihood of detection of observation and increases its safety.

When fogging the protective glass 4, when rain drops or snow flakes fall on its outer surface, the transparency of the optical receiving path of the device decreases as a result of light scattering on optical inhomogeneities. The increase in light scattering in the inventive device is recorded by an optoelectronic system consisting of optically coupled through the optical surface of the protective glass 4 within the aperture of the lens 2 of the LED emitter 10 and the photodetector 11.

The LED emitter 10 is controlled by a power supply and control unit 6 and operates primarily in a pulsed mode with a pulse repetition rate, for example, 0.01 Hz and a pulse duration, for example, 100 μs. When the signal from the photodetector 11 increases and its predetermined reference value exceeds the normal operating conditions, which may indicate an increase in scattering on the surface of the protective glass 4 due to fogging or precipitation, the control circuit of the additional heating element 9 located in the power and control unit 6, includes a heating circuit for the additional heating element 9. The additional heating element 9 heats the protective glass 4. With increasing temperatures protective glass 4 Moisture evaporates from its surface, scatter signal decreases, and when its value reaches a predetermined reference value, the control circuit further heating element 9 turns off the heating circuit 9, an additional heating element.

Thus, the use in the claimed utility model of the totality of the claimed features ensures the achievement of the technical result indicated in the application, namely, it increases the efficiency of the heater and reduces energy losses associated with heating of the elements of the monitoring device (video camera and protective glass) under adverse weather conditions.

Claims (9)

1. The monitoring device, comprising a protective casing and a power and control unit located inside it, a video camera with a lens and a heating element with a thermostat, are electrically connected to the power and control unit, and the protective casing has two holes in the ends, one of which is for the video camera lens and equipped with a protective glass, and the other is designed to accommodate the inputs and outputs of the cables, characterized in that the heating element is installed inside the camera body. 2. The monitoring device according to claim 1, characterized in that the thermostat is installed inside the camera body. 3. The monitoring device according to claim 1, characterized in that the thermostat is made in the form of a bimetallic plate. 4. The monitoring device according to claim 1, characterized in that the thermostat is made in the form of a thermocouple. 5. The monitoring device according to claim 1, characterized in that the protective glass is equipped with an additional heating element electrically connected to the power supply and control unit. 6. The monitoring device according to claim 1, characterized in that it is equipped with an LED emitter and a photodetector, each of which is electrically connected to the power supply and control unit, the photodetector being optically coupled to the LED emitter through the optical surface of the protective glass within the lens aperture, and the unit power supply and control additionally includes a module for measuring the power of the light flux of the LED emitter reflected from the optical surface of the protective glass, and a control circuit for additional grevatelnym element. 7. The observation device according to claim 5, characterized in that the wavelength of the radiation of the LED emitter lies in the infrared range of the spectrum. 8. The monitoring device according to claim 5, characterized in that the power supply and control unit is additionally equipped with a module for generating pulsed electrical power to the LED emitter. 9. The observation device according to claim 1, characterized in that the inner surface of the protective casing is covered with a layer of heat-insulating material.