DE1648280C3 - Device for determining the temperature of a flowing gas - Google Patents

Description

The invention relates to a device for determining the temperature of a flowing Gas with a gas sampling tube and a thermocouple arranged therein, which at a distance of one arranged within the gas sampling tube. also protective tube through which the gas flows is surrounded.

From HS-PS 2 006 469 there is already a device known for measuring the temperature of a flowing gas, a gas sampling pipe being provided is. which is inserted approximately concentrically in a gas line and in which several other pipes are arranged concentrically to one another and to the gas sampling pipe; all tubes have roughly the same Distance to each other and are traversed by the gas as a whole. On the outside of the inside A thermocouple is attached to each pipe, which keeps the temperature of the associated with the gas Pipe measures and with the rotary switch of a temperature display instrument arranged outside the gas line communicates. A pipeline is helical around the gas sampling pipe laid around, through which a medium for indirect heat exchange can be passed can. If, during a measurement with this device, the thermocouples indicate that For example, a heat radiation that is too strong compared to the temperature of the flowing gas is exerted outside inward on the G ^ sampling tube, then through the helical Pipeline a cooling medium passed through, which is intended to generate a counter-directed radiation, whereby the radiation losses are neutralized by ropes. Such a device is extremely complex and complicated and guaranteed due to the temperature measurement of the walls of the inner In the end, pipes are not yet sufficiently accurate Measurement result.

Another known 1 temperature measuring device

iS for gases (GB-PS 599 946) is mainly used for exhaust gas or Exhaust pipes used by internal combustion engines. Here one ends of a thermocouple protrude dun h a circumferential opening in an exhaust pipe into it, while the other ends up

Γιη are the outside of the exhaust pipe. the The ends of the thermocouple are held together with a milliammeter connected in parallel so that that the temperature difference between the inner and outer ends is determined. Of course this does not allow the actual temperature to be determined (which is not the intention either is), but m ;; r. wants - provided the conditions remain the same - from the respective temperature difference the one generated by the machine

Derive power by taking certain correction values into account. Since the Ci; isströmungsratni> ve as well as the external radiation can change many times during operation and some find the Simply insert the thermocouple freely into the exhaust gas meter, With this known embodiment, a constant and accurate measurement of the flowing Gas during the entire operation.

In another known temperature measuring device (FR-PS I 466 578) are in a space of Two thermocouples are provided for pipe section through which flue gases flow. \ on which one in the center and the other is arranged on an inner wall of the pipe section. a third thermocouple is also

half of the pipe section and attached at a distance from it. The pipe section can, given! All be double-walled, in which case there is insulating material between the two walls. With the help of the three thermocouples, the mean temperature of the flue gases is determined, including the thermocouples with an electrical Comparator related. Since in this known embodiment the measured values of the; in \ eischiedenen Place arranged internal Thormo elements and the thermocouple arranged outside the pipe section must be processed, results in a complicated comparison facility, which greatly increases the cost of such a measuring device. At the high cost of such a device contributes to an effective insulation of the pipe section without thereby increasing it the temperature of the inner wall of the gas sampling pipe (through absorbed radiant energy) via the actual gas temperature can also be counteracted significantly.

After all, it is widely known from practice to use thermocouples for measuring gas temperatures to be used, for example, for the determination

determination of the secondary air temperature of a device for cooling cement clinker is the case. Here, too, the thermocouples are in a gas sampling tube arranged, where »nan tried that undesired extraneous radiation influences on the thermocouple by using a likewise the protective tube through which the gas flows and in which the thermocouple is located. This protective tube reflects a certain proportion of the gas taken up by the outer gas sampling tube and inwardly emitted radiation and thus reduces the proportion that reaches / around the thermocouple the total external radiation. In this way, however, the adverse influence of Only reduce external radiation on the temperature measurement, but do not switch it off completely.

The invention is therefore based on the object of providing a device of the type mentioned at the beginning create, by which with relatively simple means the complete exclusion of the radiation influence and thus a particularly precise measurement of the gas temperature is made possible.

This object is achieved according to the invention in that in the space between the gas sampling pipe and protective tube auxiliary thermocouples are arranged, which with the thermocouple in the sense a correction of the measured value with respect to the interfering influence of an external radiation are.

The invention is based on the following knowledge:

A part of the external radiation impinging on the gas sampling pipe is absorbed and the rest reflects. The absorbed radiation energy increases the temperature of the gas sampling pipe about the actual gas temperature. The resulting temperature gradient between the gas sampling pipe and protective tube leads to a heat flow through radiation from the outer gas extraction tube to the inner protective tube. Part of this radiation is in turn absorbed by the inner protective tube, the rest reflects. This creates a temperature gradient between i! ° m of the inner protective tube and the main thermocouple arranged therein. that to a certain radiation from the protective tube leads to the main thermocouple.

The latter, the measured value of the main thermocouple falsifying radiation component can now be detected indirectly by using the Auxiliary thermocouples determines the radiation from the gas intake pipe. You know the geometric and radiation-physical properties of the measuring device, one can determine from this the auxiliary thermocouples determined the radiation from the gas sampling tube to the one falsifying the measured value Close the radiation of the protective tube (which in practical operation takes place via a calibration curve).

In the device according to the invention, the Hauptthermuelement is freely within the Protective tube, which in turn - as known per se - arranged in the gas sampling tube of the device is, both the protective tube and the one located between the protective tube and gas sampling tube The gas flows through the gap. If one now finds with such a device, that the gas sampling tube absorbs radiant energy from the flowing gas, whereby whose temperature increases above the actual gas temperature and thus a temperature gradient between If the gas sampling tube and protective tube creates, then it would normally be obvious to have a strength Wirnveisoiation to provide such as for example is also the case in the first-mentioned known embodiment (US-PS). It has now, however pointed out that - as already mentioned further Qben - an effective isolation not only difficult, but also extremely complex in terms of construction.

ίο The invention solves this problem in a meaningful way Arrangement of auxiliary thermocouples in the space between the inner protective tube and the gas sampling tube. These hip thermocouples look at the: a.m most suitable Measuring points - separated by the protective tube wall - around the main thermocouple so that all act on the main thermocouple and influencing the measurement result of this thermocouple Radiations can be detected in an optimal way. Since the auxiliary thermocouples with the Main thermocouple in the sense of a correction of the measured value with regard to the interference of an external one Radiation are interconnected, can be extremely accurate with the device according to the invention Carry out measurement of the temperature of a flowing gas, with an insulation of the gas sampling pipe can practically completely be omitted, which leads to a simple structural design of the device contributes.

The auxiliary thermocouples are expediently connected to a device that is used to eliminate the Dependence of the correction value on the direction of radiation forms a sealed mean value from the measured values of the individual auxiliary thermocouples.

In the following the invention is based on an embodiment illustrated in the drawing described. F.s shows

F i g. 1 shows a diagram of the structural design of the device.

4J F i g. 2 shows a diagram of the processing of measured values.

The in F i g. 1 shown device for determining the temperature of a flowing gas contains an outer gas sampling tube 1 and a protective tube 2 arranged concentrically therein.

The two tubes 1 and 2 are in the direction of arrow 3 of the to be measured in its temperature Gas flow permeated, which is sucked through the two tubes by means of a fan. On the gas inlet side there is a double screen 4 to prevent direct radiation into the two Tube.

A main thermocouple 5 is arranged in the inner protective tube 2. In the space between the gas sampling tube 1 and the protective tube 2 are a number of auxiliary thermocouples 6, which are preferably evenly distributed over the circumference (when using four auxiliary thermocouples 6, these are offset from one another by 90 on the circumference).

The thermal voltage supplied by the main thermocouple 5 is denoted by H; the thermal voltages of the auxiliary thermocouples 6 have the reference symbols A ₁ to A _n .
The external radiation impinging on the outer gas sampling tube 1 is characterized by the dashed lines 7, the radiation emitted by the gas sampling tube 1 in the direction of the protective tube 2 by the dashed lines 8 and the radiation emitted by the

Protective tube 2 in the direction of the main thermocouple 5 emitted radiation by the dashed lines 9.

F i g. 2 shows schematically the processing of the thermal voltages Ή and A _t to A supplied by the main thermocouple 5 and the auxiliary thermocouples 6.

The measured values A, to A 'of the auxiliary thermocouple elements 6 are fed to a device 10, which for the purpose of eliminating the dependence of the correction value from the radiation direction of the outer FremdsUahlung from the measured values A ₁ to A _n of the individual auxiliary thermocouples forming a weighted average.

This averaging device 10 and the main thermocouple 5 delivering the measured value H are connected to a difference-forming device 11 which determines the difference between the measured value H of the main thermocouple 5 and the mean value of the measured values A 1 to A _n delivered by the auxiliary thermocouples 6. This difference is a measure of the external radiation impinging on the device and the resulting falsification of the measured value of the main thermocouple 5.

The device 11 used to form the difference is connected to a correction value generator 12, which contains a calibration curve field which is stored, for example, in a process computer or in analog technology realized by a computing circuit!

ίο will. This correction value generator 12 is taken into account! the geometric and radiation-physical properties of the measuring device and supplies a correction value which subtracts a correction element 13 from the measured value H of the main thermocouple 5!

will. In this way, the influence of the dei External radiation from the main thermocouple f Incorrectly too high specified gas temperature exaki corrected and one receives the real gas temperature at the output of the correction element 13.

1 sheet of drawings

Claims (3)

Claims. 1. Device for determining the temperature of a flowing gas with a gas vent ■ pick-up tube and a thermocouple arranged in it, the same at a distance from one arranged inside the gas sampling tube is surrounded by the protective tube through which the gas flows. dadurcjj marked that in the Zwischenjraiuij \ between-ijC & delivery pipe (1) and protective tube (2) auxiliary thermocouples {6) arranged are that with the thermocouple (5) in the sense of a correction of the measured value with respect to the Interfering influence of external radiation are interconnected. 2. Apparatus according to claim 1, characterized in that the auxiliary thermocouples (6) are connected to a device (10) which to eliminate the dependence of the correction value on the radiation direction from the MeLiwertcniyi, to A _n ) of the individual auxiliary thermocouples (6) weighted mean. 3. Device according to claims 1 and 2. characterized in that the protective tube (2) arranged main thermocouple (5) and the one connected to the auxiliary thermocouple (6) Averaging input (10) with a difference indicator Device (11) are connected. the controller generator (12) containing a calibration curve field with one at the same time the main thermocouple (S) is connected to the correction element (13). the determined Correction value avail. The measured value of the main thermocouple is subtracted.