CS228191B1 - Air screen for radiation thermometer - Google Patents

Description

The invention relates to an air curtain of a radiation thermometer for measuring the temperature of a moving sheet during its drying or heating, in particular for measuring the temperature of a textile during drying. and a fixation arranged in front of the radiation thermometer entry window.

Radiation thermometers are already a common part of - systems for measuring and controlling those technological processes where heating or drying of a continuously moving mttrial in closed furnaces, such as granulated feed or food, polymer foils, paper, textiles, etc. The products of this heating or drying, released from the material, are then removed, including water vapor, by the drying medium, which is most often air.

The thinned products of the technological process, hereinafter referred to as the products, are formed most often by vapors - organic oils, oligomers of organic substances, etc., and settle on all internal surfaces of the furnace or dryer and condense on the radiation window or lens. This condensation is very undesirable as condensation products are impermeable to infrared radiation and the thermometer signal gradually decreases.

Despite the risk of condensation on the objective of the radiation thermometer, hereinafter referred to as the thermometer, these thermometers are widespread for the benefit of contactless temperature sensing and for a low time constant and relatively easy installation of the measuring system.

The disadvantages include the deterioration of the optical transmission of the lens, the absorption of infrared radiation in the environment - between the object and the thermometer, and the dependence of the output data on the emissivity of the object being sensed.

The risk of condensation on the thermometer lens is solved by known manufacturers of these polymers. of ukem, or transverse air curtain installed in front of the thermometer inlet window. Said orifice according to the known embodiment comprises a fan and a rectangular duct from which a cold stream exits from the outside of the intake air in a direction substantially perpendicular to the optical axis of the thermometer. The transverse flow entrains a part of the internal polluted environment and the resulting air stream exits predominantly into the external environment, i.e. into the external environment of the technological, hereinafter referred to as the drying machine.

The amount of exhaust air depends on the geometry and the optical system of the thermometer. In known devices equipped with a conventional optical system, i.e. a lens or hollow mirror, and in which the optical systems due to the low sensitivity of the sensor itself must be very large, the amount of air blown by the air curtain is also very large.

This large amount of cold air cannot be blown out, for example, into the interior of the drying machine, otherwise the heat balance of the machine will be considerably burned.

The air curtain of known devices almost eliminates the risk of flue gas condensation on the exit window of the thermometer, but the energy consumption required to convey a large amount of air through the air curtain increases, the thermocomplexes and the dimensions of the thermometer including the curtain increase. of the measured pattaial.

The disadvantage of the energy intensity, the large dimensions, and especially the absorption of radiation in the environment between the measured object and the thermometer is partly eliminated by the air curtain according to the invention, which consists of an annular nozzle opening towards the optical axis of the radiation thermometer. the nozzle is discharged into a pressure chamber circumscribing. an annular nozzle along its outer periphery, the annular nozzle being coaxial with the optical axis of the radiation thermometer.

An advantage of the air curtain according to the invention is, in particular, a considerable increase in the coherence and stability of the passage by means of radiation thermometers. Another advantage is the prolongation of the cleaning interval of the inlet window of the radiation thermometer and thus the increase in the length of the whole device on which the radiation thermometer is located.

. The air curtain according to the invention is shown schematically in the accompanying drawing, in section, together with the entire technological node serving to the temperature of the pollinating surface heating during its heating or drying.

The radiation thermometer consists of a housing 1, in which a detector 6 with an unspecified optical system, bounded by an entrance window J, is mounted. On the outer peripheral wall of the housing 6 is mounted a cooling system 6 formed in the illustrated embodiment by a heat exchanger. an oaso-visual source of cooling pressurized air.

At the outlet 4 of the cooling system 4 is attached a body Z of the pressure chamber g, which is fixed to the lower part of the housing 6. An opening is formed in the central part of the body from the pressure chamber g

g. The body Z of the pressure chamber g is arranged in such a way that the axis of the opening g lies in the optical axis of the detector 6. in the lower part of the body Z of the pressure chamber g, the ring 54 is displaceably mounted. formed in an exemplary embodiment by a hollow screw with an external thread, the hole of which is coaxial with the hole. g formed in the body Z of the pressure chamber g and has the same diameter.

Between the middle part of the Z-body of the pressure chamber and the ring. . 10, araococcus slot 11 is provided for feeding. - compressed air into the bore - G - A - - this - orifice - £ - -into 'prosto- _e ru 12 between the radiation thermometer and the potybuuícím plošiým formations -' 13. ·

The central part Z1 of the body Z of the pressure chamber g, the thread 10 and the annular gap 11 together form an annular nozzle 110.

In the space 12 between the radiation thermometer and the moving sheet formation 13, for example a fabric belt, there are exhausts of the technological process which tend to condense on the entrance window J of the detector 2.

In the operation of the thermometer, the cool air from the pressure distribution entering the thermometer via line 4 is preferably forced through, for example, the heat exchanger of the cooling system 4, thereby achieving a very desirable cooling of the detector or thermo preamplifier. the amplifiers grow with decreasing thermometer temperature. The partially heated air then passes through the pressure chamber 8 and passes through the annular nozzle 110, forming a conical velocity formation at the outlet.

All of the exiting air in the space behind the annular nozzle 110 combines into a single air stream 14 moving in the optical axis of the thermometer towards the moving surface 13. By suitable air pressure and geometry of the annular nozzle 110 it can be achieved that clean air or drying flows from the nozzle to almost the measured object, in the vicinity of which it dissipates.

The consequence of this is to eliminate the disadvantage of absorption of radiation by the combustion or drying products contained in the interior of the furnace and of course to prevent condensation of these products at the entrance window J of the detector 2.

A positive factor here is the fact that, with a defined field of vision, the space in which the infrared radiation can be absorbed in the environment has the shape of a cone tapering toward detector 2, which is roughly the same shape as the gradually expanding air flow 14 exiting the detector. annular nozzles 110.

Optimum matching of the two spaces can be achieved by varying the pressure at the inlet to the annular nozzle 110 or by varying the width of the annular gap 11 of the annular nozzle 110 by appropriately adjusting the aforementioned annular 10, for example.

When using a sensitive sensor, the dimensions of the optical system can be greatly reduced compared to conventional dimensions. Consequently, the diameter of the annular nozzle and thus the air flow through the nozzle can be reduced to a value which does not substantially affect the heat balance of the furnace or drying chamber.

Claims (4)

SUBJECT OF THE INVENTION An air curtain of a radiation thermometer for measuring the temperature of a moving sheet during drying or heating, in particular for measuring the temperature of a fabric during drying and fixation, arranged in front of the entrance window of a radiation thermometer detector, characterized by an annular nozzle (110); the outer edge of the annular nozzle (110) extends into a pressure chamber (8) surrounding the annular nozzle (110) along its entire periphery, the annular nozzle (110) being coaxial with the optical axis of the radiation thermometer thermometer. Air curtain according to claim 1, characterized in that the annular nozzle (110) is formed by a space between two frustoconical shells whose apexes lie on the optical axis of the radiation thermometer in the section between the air curtain and the measured sheet (13). Air curtain according to one of Claims 1 to 2, characterized in that one of the frustoconical shells, whose sheaths form an annular nozzle (110), is displaceably mounted in the body (7) of the pressure chamber (8). Air curtain according to one of Claims 1 to 3, characterized in that a cooling system (4) is enclosed in front of the pressure chamber (8) surrounding the detector (2) and the optical system of the radiation thermometer. air temperature lower than 25 ° C.