CS214998B1 - Meter of capacity of the thermal radiation - Google Patents

Abstract

An apparatus for measuring the power of a heat radiation comprises a disc 5 bordered by a heat sensitive element such as an electrically conductive filament (6). Part of the filament 6 is positioned in a heat radiation flux or jet (4) and the disc is rotated at a stabilized speed. Connected to the sensitive element is a meter (7, Fig, 1, not shown) for registering the variations of the conductivity, that is the temperature. A system may comprise at least three apparatuses (36, Figs. 13 & 14 not shown) spaced around the flux or jet. In an alternative configuration to that shown in Fig. 2 a heat sensitive wire filament is threaded back and forth in a zig-zag fashion between two spaced discs (Figs. 7 & 8 not shown). A bimetallic strip may replace the disc and filament. Any resulting deflection is measured by a pickup 26, Fig. 9 or by means of mirrors 31 positioned on the end of the strip so as to reflect light from a source 33 onto a scale 35. <IMAGE>

Description

SUMMARY OF THE INVENTION It is an object of the present invention to provide a heat radiation power meter whose construction makes it possible to increase the measuring accuracy for thermal radiation in continuous operation and also to increase the reliability of the heat radiation power meter and measuring systems made therefrom.

This object is achieved by the heat radiation power meter according to the invention, which is based on the fact that the electrically conductive fiber is wave-bent and formed into either a flat ring or a cylinder, the electrically conductive fiber being supported on a main disk which is mounted on an output shaft rotating. perpendicular to its axis of rotation.

Advantageously, when placing the rotational axis of the rotary gear output shaft transverse to the heat radiation stream, a tube in which the heat radiation stream is enclosed is mounted on the foot, a ring is rotatably mounted on the tube, the ring and rotary assembly being rigidly connected to the bracket.

When placing the rotational axis of the rotary gear output shaft transverse to the heat radiation stream, it is desirable that the rotary gear output shaft accommodates an additional disk parallel to the main disk between which the electrically conductive fiber would be tensioned, the distance between the main disk and the additional disk cross section of heat radiation current.

Preferably, the electrically conductive fiber is zigzagged between the main disk and the additional disk.

It is also preferred that the main disc and the auxiliary disc are made of dielectric material.

The invention guarantees the operation of the heat radiation power meter in continuous operation.

The meter according to the invention has high technical-economic parameters, which is guaranteed by allowing measurement in a wide power range of thermal radiation currents without any design changes to the meter and without the use of instruments and materials manufactured by the industry as assembly elements.

The advantage of the invention is also that it is very easy to replace the meter elements in the event of their failure. Moreover, the small dimensions of the meter allow its placement at virtually any point in the path of movement of the thermal radiation stream, further increase its operating characteristics and reduce its manufacturing costs.

A further advantage of the invention is that it reduces the residence time of the sensor in the heat radiation zone and increases its cooling rate, thereby increasing the reliability of the heat radiation power meter.

In addition, the invention provides a sensor rotational speed that avoids affecting measurement accuracy for thermal radiation by accidental air currents and ambient temperature fluctuations at the location of the heat radiation power meter.

In addition, the invention allows the rotation speed of the sensor to be varied, which guarantees the possibility of measuring the output of thermal radiation in large power regions.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an overall block diagram of a heat disc power meter with a main disc where an electrically conductive fiber is used as the sensor in the case where the output shaft axis is on which Fig. 2 is a schematic view of the meter in the direction of arrow A in Fig. 1, 3 of the meter of Fig. 1 for the case in which the axis of rotation of the output shaft of the rotating device lies in the direction of heat flow Fig. 4 shows a schematic view of the meter in the direction of arrow V in Fig. 3, Fig. 5 shows the meter of Fig. 1 provided with a tube in which the heat radiation flow is closed; 5, FIG. 7 shows the meter according to FIG. 1 with an additional disc, FIG. Β a view of the meter in the direction of the arrow D in FIG. 7, FIG. Fig. 10 is a view of the meter in the direction of the arrow E in Fig. 9, Fig. 11 is a schematic view of the meter according to Fig. 9 for the heat radiation power meter. Fig. 12 is a view of the meter in the direction of arrow F in Fig. 11, Fig. 13 is an overall diagram of a heat radiation power measuring system made on the basis of a heat radiation power meter, 13, FIG. 14 is a view of the measuring system in the direction of arrow G in FIG. 13.

The heat radiation power meter comprises a rotating device 1 - Fig. 1 - with an output shaft 2, whose axis of rotation 3 lies transverse to the heat radiation stream. According to this variant of the embodiment, a main disk 5, which is preferably made of dielectric material, is mounted vertically on the output shaft 2 to the axis of rotation 3 of the output shaft 2. In the thermal radiation stream 4 there is a sensor having the possibility of displacement at a stabilized speed and which in this embodiment variant is made of an electrically conductive fiber 6 - Fig. 1 - Fig. 2, which is in the plane of rotation of the main disc 5 - Fig. 2. bent and fixed on its circumference. The meter also comprises a temperature sensor 7 for temperature changes due to the effect of thermal radiation, to whose inputs the ends 9 of the electrically conductive fiber 8 are connected via the collector rings 8.

Figures 3 and 4 show the connection of the heat radiation power meter similar to that shown in Figures 1 and 2, but in this case the axis 3 of the output shaft 2 of the rotating device 1 is positioned in the direction of the thermal radiation stream 4.

In another variant, the heat radiation power meter comprises a tube 11 mounted on a support foot 10 - Fig. 5 - in which the heat radiation stream 4 is closed. The support foot 10 is located on the base plate 12. A ring-shaped element 13 is rotatably mounted on the tube 11 and connected via a belt drive 15 to a motor 14 located on the base plate 12. The belt drive 15 is formed by a drive pulley 16, a drive belt 17 and a driven pulley 18. The ring 13 and the pivot device 1 are rigidly connected to each other by a bracket 19 - Figs. 5, 6 - so that the axis 3 of the pivot output shaft 2 lies transverse to the heat radiation stream 4. The rotating device 1 is connected to the outputs 20 of a not shown voltage source via contact rings 21 - Fig. 5 - located on the ring 13. The collector rings 8 - Fig. 5 - are connected to the inputs of the recorder 7 via another pair of collector rings 22 located on the ring 13. .

In another embodiment, the heat radiation power meter comprises an additional disc 23 - Figs. 7, 8, which is located on the output shaft parallel to the main disc 5. The additional disc 23 is made of dielectric material. The distance between the main disc 5 and the additional disc 23 - Fig. 7 - must be greater than the cross-section of the heat radiation stream 4. The sensor is in this variant also in the form of an electrically conductive filament 6, which is zigzagged between the main disk 5 and the additional disk 23 - Fig. 7 - and placed on their circumference. Next, this meter wiring is analogous to the meter circuit shown in Figure 3.

In yet another variant of the heat radiation power meter, the sensor is in the form of a strip 24 (Figs. 9, 10) which is made of bimetal. The width of the strip 24 - Fig. 10 - must be smaller than the cross section of the heat radiation stream 4. the length of the belt 24 must be greater than the cross section of this current 4. The meter is provided with a yoke 25 - Fig. 9 - located on the output shaft 2. At the ends of the yoke 25 the ends of the yoke 24 are connected so that the yoke 24 shields the yoke 25 upstream 4 Instead of the recording apparatus 7 - FIGS. 1, 3, 5, 6 and 7 - it is sufficient to use a well-known longitudinal movement sensor 26 - FIG. 9 whose inlet 27 communicates with the center of the strip 24 as its pivot point.

In yet another variant of the heat radiation power meter, the sensor is made in the form of two belts 28, 29 - Figs. 11, 12 - which are fixed at one end to the output shaft 2 so that the plane of each strip 28, 29 is perpendicular thermal radiation.

The longitudinal movement sensor 26 comprises mirrors 30, 31, which are located at the free ends of the belts 28 and 29. As the output shaft 2 rotates, the light beam 32 from the light beam emitter 33 alternately impinges on the mirrors 30, 31 - e.g. A reading scale 35 is located in the path of the reflected light beam 34.

The meters 36 according to the invention can be assembled in a measuring system for measuring the heat radiation output - Figs. 13, 14 -. The meters 36 are positioned at an angle of 120 ° to each other such that their electrically conductive fibers 6 'overlap the cross section of the thermal radiation stream 4.

The heat radiation power meter operates as follows: The sensor placed in the thermal radiation stream 4 receives a portion of its energy, which causes the sensor temperature to rise. The sensor rotates at a stabilized speed, which ensures its temperature stabilizes at a specified level.

If the sensor is in the form of an electrically conductive fiber 6 -. Fig. 1 - its ends 9 are connected to a recording apparatus 7, which is calibrated in units of thermal radiation power and measures the change in electrical resistance of the electrically conductive fiber 6.

If the electrically conductive filament 6 - Figs. 1 and 2 - is mounted on the main disk 5 and the rotation axis 3 of the output shaft 2 of the rotating mechanism 1 is positioned transversely to the heat radiation stream 4, the heat radiation power meter measures the power power density distribution - in its cross-section.

If the axis 3 - Figs. 3 and 4 - is directed longitudinally with the thermal radiation stream 4, the heat radiation power meter measures the integrated power of the thermal radiation 4.

It is advantageous in these two variants that, with a minimum thermal radiation current 4 - Figs. 1, 2, 3, 4 - the wave stability of the electrically conductive filament 6 increases with increasing speed of the output shaft 2 due to the plane of deflection of the electrically conductive filament. 6 is coincident with the plane of action of external forces having the nature of centrifugal forces.

Such an optimum configuration allows the use of an electrically conductive fiber 6 with a minimum cross-sectional area and thus minimizes the inertia of the meter.

In the case where the rotating device 1 is firmly connected to the ring 13, which is rotatably mounted on the tube 11, by means of a bracket 19 - FIGS. 5, 6, the electrically conductive filament 6 still has the possibility of additional movement around the thermal radiation stream 4. In this case, the heat radiation power meter measures the spatial distribution of the power density over any cross section of the heat radiation stream 4.

When the electrically conductive filament 6 (FIGS. 7, 8) is tortuously tensioned between the main disk 5 and the additional disk 23, the meter measures the integrated power of the thermal radiation current 4.

If the sensor is in the form of a belt 24 - fig. 9, 10 - or in the form of two belts 28, 29 - fig. - 11, 12 - then a longitudinal movement sensor 26 which is calibrated in units is used instead of the recorder 7. thermal radiation output.

Radiation changes the shape of the strip 24 - Fig. 9, 10 - or other strips 28, 29 - Fig. 11, 12 - and according to the magnitude of these shape changes the power of the thermal radiation stream 4 is determined after appropriate calibration.

The center of the strip 24 - Figs. 9, 10 - whose ends are fixed to the yoke 25 is in direct contact with the inlet 27 of the sensor 26, which measures the magnitude of these shape changes.

The strips 28, 29 - Figs. 11, 12 - are deformed when cut by the thermal radiation stream 4, thereby causing a change in the length of the reflected light beam 34. The magnitude of this change is registered by the reading scale 35 of the sensor 26.

Instead of the mirrors 30, 31, a polished surface (not shown) that is formed at the free ends of the belts 28, 29 can be used.

To determine the position of the power maximum of the thermal radiation current 4, a heat radiation power measurement system consisting of three heat radiation power meters 36 can be used - Figs. 13, 14 Moving the meters 36 by 120 ° allows simultaneous measurement of the integrated power and the position of the thermal radiation power maximum in the cross-section of the thermal radiation stream 4.

Claims (5)

CLAIMS 1. A heat radiation power meter comprising a sensor placed in a heat radiation stream to which an apparatus for recording temperature changes of the sensor due to heat radiation is connected, the sensor being an electrically conductive fiber and connected to an output shaft located away from the heat radiation stream; provided with a rotating device, characterized in that the electrically conductive filament (6) is wave-bent and formed into either a flat ring or a cylinder, the electrically conductive filament [6] being supported on a main disc (5) which is supported on the output a shaft (2) of the rotation device perpendicular to its axis of rotation (3). Meter according to claim 1, characterized in that a tube (11) is mounted on the support foot (10) when the rotation axis (3) of the output shaft [2] of the rotary device (1) is transverse to the heat radiation stream (4). in which the heat radiation stream (4) is closed, a ring (13) is rotatably mounted on the tube (11), the breast (13) and the pivot device (1) being rigidly connected to the bracket (19). 3. A meter according to claim 2, characterized in that, when the axis of rotation (3) of the output shaft (2) is positioned transversely to the heat radiation stream (4), it is on the output shaft (2) of the rotary device (1). 1) an additional disc (23) is arranged parallel to the main disc (5) between which the electrically conductive fiber (6) is tensioned, the distance between the main disc (5) and the additional disc (23) exceeding the cross-sectional area radiation. A meter according to claim 4, characterized in that the electrically conductive fiber (6) is zigzagged between the main disc (5) and the additional disc (23). A meter according to claim 4 or 5, characterized in that the main disc (5) and the additional disc (23) are made of dielectric material.