CS202243B1 - Fireproof radiating body - Google Patents

Description

The invention relates to a radiator body in which several temperature zones which differ from one another and which are clearly separated from one another can be realized on one temperature radiating element.

In the field of thermal technology, it is often necessary to realize a temperature of exactly known magnitude on the test element. This is particularly necessary, for example, in the verification of radiation pyrometers. This is done by heating a cavity forming a black body in the test furnace to a temperature that is uniformly distributed over the entire sighting surface.

This temperature is then determined by the included precision thermocouple and serves as a reference temperature for the controlled radiation sensor. Since such sensors need to be verified over their entire temperature range, the temperature of the emitting target must be gradually increased and comparative measurements taken at several points in the temperature range of the sensor. However, since it is always necessary to wait for the temperature to stabilize from one measuring point to the other, which is generally 20 to 40 minutes, the verification of these sensors is always a lengthy matter. The same applies to other temperature measurements, where it is necessary to accurately display temperatures of different levels.

These disadvantages are overcome by the refractory radiator, in particular for testing the radiation pyrometers according to the invention, which consists of a plate whose face is provided with protrusions po242243 (11) (B1) (51) Int. Cl. ³

G K 11/12

G 01 J 1/14 degrees of increasing height, each of which is provided with a thermocouple, the protrusions being separated from each other by recesses and grooves formed against the recesses on the back of the plate so that the protrusions are connected to each other only by a thin membrane. According to a preferred embodiment, the successively increasing projections are arranged in the form of annular, circular segments, parallel steps or arranged to form a chessboard-spaced post over the entire surface of the base body.

An advantage of the invention is the possibility to heat the active part of the emitter simultaneously to several different temperatures, at a constant, underlying temperature of the heating system. Each relief surface has its own temperature given by the height of the projection, i.e. the distance of the active relief surface from the heating system. Thus, it is possible, for example, to check the radiation sensors gradually over their entire temperature range without having to change the basic temperature of the heating system and wait for each set temperature to stabilize each time. The sensor field of view simply shifts and focuses on different locations in the relief. Thus, the time required for the overall verification is reduced to a fraction of the original time required.

The refractory radiator according to the invention is shown in the accompanying drawing, in which Fig. 1 is in the form of a circular plate with concentric circular protrusions, which is shown in plan view in Fig. 2;

2D2 243

202 243 is a relief formed by segments cut in the body of the body, FIG. 4 is a plan view of the plate; FIG. 5 shows a similar target whose relief is formed by stair protrusions and a continuous recess in one direction; 7 shows a radiator body in which the plate relief is formed by a series of projections separated by an intermittent recess in both directions, and FIG. 8 is a plan view of the body.

As can be seen from the figures, the radiating body consists of a plate 1 made of a refractory material, which on the front surface is provided with protrusions 2 of different height, separated by a recess 5. The rear surface 3, i.e. the surface on which the heating medium acts 4, located opposite the recess 5, so that the connection of the individual projections 2 is formed by a mere membrane

8. A circumferential groove 6 is formed around the periphery of the plate 1 to attach it to the heating thermal system 9, such as a reference source of heat radiation. The thermocouples 7 _t 'are fixed to the surface of the individual relief surfaces.

The individual relief surfaces are heated at a constant temperature of the heating system to a different temperature, which is given by the height of these projections 2 and the coefficient of thermal conductivity of the material used. Due to the recesses 5 and the grooves 4, these temperatures are sharply separated from one another and do not interfere with or overlap one another. The temperature of the individual relief projections 2 is measured by a thermocouple 7 attached.

The described device can be used in various areas of heat and measuring tapes. It can be used to verify radiation pyrometers, as a reference heat source for the needs of thermovision, as a thermal radiation source for comparative measurements in the photothermometry field, as a control device for detecting the blackness of the film layer of negative photographic materials in infrared and many other uses.

Claims (5)

1. A refractory radiator, in particular for testing radiation pyrometers, characterized in that it consists of a plate (1), the front surface of which is provided with protrusions (2) of gradually increasing height, each of which is provided with a thermocouple (7). the protrusions (2) are separated from each other by a recess (5) and grooves (4) are formed against the recesses (5) on the rear side of the plate (1) so that the protrusions (2) are connected to each other only by the membrane (8). 2. The refractory radiator according to claim 1, characterized in that the successively increasing projections (2) are arranged in the form of an annulus. OF THE INVENTION 3. The radiation refractory body according to claim 1, characterized in that the progressively increasing projections (2) are arranged in the form of circular segments. 4. The refractory radiator according to claim 1, characterized in that the successively increasing projections (2) are arranged in the form of parallel steps. 5. A refractory radiator according to claim 1, characterized in that the successively increasing projections (2) are arranged to form checkerboard posts distributed over the entire surface of the base body.