RU27693U1 - THERMAL INFRARED RADIATION SIMULATOR - Google Patents

Description

THERMAL INFRARED RADIATION SIMULATOR

The utility model relates to simulators of infrared radiation of real objects and can be used as a target on an open path.

Known thermal simulator of infrared radiation, made in the form of a flat radiating plate having deep concentric grooves, with a heat-resistant coating in combination with a reflector (hood) in the form of a truncated cone with mirrored inner walls. The thermal simulator is equipped with a thermostatic heating system, including a heating element and a control unit. To maintain a given radiation level, only one temperature parameter is monitored. (Makarov A.S., Omelaev A.I., Filippov V.L. Introduction to the technique of development and evaluation of scanning thermal imaging systems. Kazan, “Unpress, 1998, pp. 200-201).

A disadvantage of the known simulator is its limited capabilities that do not allow reproducing various temperature conditions of the external surface of objects in time due to the difficulty of ensuring the isothermality of the walls of the emitter under wind loads.

The objective of the utility model is to develop a thermal infrared radiation simulator that allows you to simulate the level of infrared radiation of the external surfaces of objects in time due to the possibility of monitoring and operational control of the level of infrared radiation and the temperature of the emitting surface of the simulator.

The problem is achieved in that in a thermal infrared simulator made in the form of a radiating plate with a heat-resistant coating and equipped with a reflector, a heating element and a control unit, according to a utility model, it is additionally equipped with a radiation level sensor, in front of which

2002127388 r 7V D

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an optical filter is located with predetermined spectral characteristics and temperature sensors of the radiating plate and the environment, while the outputs of each sensor are connected to the inputs of the control unit, the output of which is connected to the heating element. A radiation level sensor with an angular aperture covering the area of the plate is located in front of the radiating plate. Sensors of the radiation level and temperature of the radiating plate are equipped with protective covers. The heating element is located behind the radiating plate in front of the reflector. The thermal simulator is provided with a heat-shielding coating. In this case, the ambient temperature sensor can be installed in the thermostat.

The utility model is illustrated in the drawing, which presents its schematic diagram.

The thermal infrared radiation simulator is a negative feedback automatic control system, which includes the following main elements: a flat radiating plate 1 coated with heat-resistant matte enamel, a radiating surface temperature sensor 2 mounted on the plate 1, an ambient temperature sensor 3, and a sensor 4 radiation levels, which is located in front of the radiating plate 1. The field of view of the sensor 4 covers the working surface of the plate 1. The sensor 4 is equipped with an optical filter rum 5. Behind the radiating plate 1 and in front of the reflector 6 there is a heating element 7, designed to provide a given temperature difference (A T) between the working plate 1 and the environment. The reflective element 6 provides a more uniform heating of the plate 1 and increases the efficiency of the simulator. The heat simulator is surrounded by a heat-protective coating 8. The outputs of the sensors 2, 3 and 4 are connected to the inputs of the control unit 9, which is designed to provide a given temperature difference (A T) between the working surface of the plate 1 by the environment, as well as the IR level

radiation plate 1, and the output of block 9 is connected to the heating element 7. To protect against precipitation and wind loads, the radiation level sensor 4 is equipped with a protective casing 10, and the temperature sensor 2 with a casing I. The temperature sensor 3, depending on the task of the experiment, can be installed in thermostat 12.

Heat-resistant coating of the working surface of the plate 1 has a high emissivity.

Thermal simulator of infrared radiation operates as follows.

The radiating plate 1 is heated by the heating element 7 and creates a predetermined spatial distribution of infrared radiation. The control is carried out simultaneously or separately, both in temperature and in radiation level, depending on the experimental conditions. The electrical signal from the temperature sensors 2 and 3, corresponding to the difference between the surface temperature of the plate 1 and the ambient temperature, as well as from the sensor 4 is supplied to the electronic control unit 9. The electronic control unit 9 maintains a predetermined temperature difference (A T). The thermal simulator using the sensor 4 has the ability to contactlessly control the level of radiation. By changing the optical filter 5, it is possible to provide a radiation level in a given spectral range of wavelengths AX. This device allows you to control the level of radiation, including the effect of reflections from background formations (sun, sky and underlying surface). Due to the low thermal inertia, the thermal simulator allows you to simulate the dynamic characteristics of thermal portraits of objects in time according to a given program.

The thermal infrared simulator is designed to test infrared optoelectronic systems on an open path.

USEFUL MODEL FORMULA

1.Thermal infrared radiation simulator, made in the form of a radiating plate coated with heat-resistant matte enamel and equipped with a reflector, a heating element and a control unit, characterized in that it is additionally equipped with a radiation level sensor in front of which there is an optical filter with predetermined spectral characteristics and temperature sensors of the radiating plate and the environment, while the outputs of each sensor are connected to the inputs of the control unit, the output of which is connected to the heating element.

2. The thermal simulator according to claim 1, characterized in that the radiation level sensor is located in front of the radiating plate with an angular aperture covering the area of the plate.

3. The thermal simulator according to claim 1, characterized in that the sensors of the radiation level and temperature of the radiating plate are equipped with protective covers.

4. The thermal simulator according to claim 1, characterized in that the heating element is located behind the radiating plate in front of the reflector.

5. The thermal simulator according to claim 1, characterized in that it is provided with a heat-protective coating.

6. The thermal simulator according to claim 1, characterized in that the ambient temperature sensor is installed in the thermostat.

Claims (6)

1. Thermal infrared radiation simulator made in the form of a radiating plate coated with heat-resistant matte enamel and equipped with a reflector, a heating element and a control unit, characterized in that it is additionally equipped with a radiation level sensor, in front of which there is an optical filter with predetermined spectral characteristics and radiating temperature sensors plates and the environment, while the outputs of each sensor are connected to the inputs of the control unit, the output of which is connected to the heating element.  2. The thermal simulator according to claim 1, characterized in that the radiation level sensor is located in front of the radiating plate with an angular aperture covering the area of the plate.  3. The thermal simulator according to claim 1, characterized in that the sensors of the radiation level and temperature of the radiating plate are equipped with protective casings.  4. The thermal simulator according to claim 1, characterized in that the heating element is located behind the radiating plate in front of the reflector.  5. The thermal simulator according to claim 1, characterized in that it is provided with a heat-shielding coating. 6. The thermal simulator according to claim 1, characterized in that the ambient temperature sensor is installed in a thermostat.