DE3031339A1 - Contact temp. sensor with fixed point - has temp. sensitive element inside fixed point material in tube - Google Patents

Abstract

A contact temp. sensor with a fixed point is a high accuracy device which provides at least one calibration point during measurement. The temp. sensitive element of the sensor is arranged w.r.t. a fixed point material so that the thermal resistance between them is low. The thermal resistance between the fixed point material and the measurement object is a multiple of that between the temp. sensitive element and the fixed point material. The conversion point of the fixed point material lies within the sensor measurement range. The fixed point material (1) may be a liquid or a solid such as a metal, metal alloy, or salt. It may be placed in ceramic, graphite, or metal tube (2) with the temp. sensitive element (5) and part of its cable.(3) in the central hole.

Description

Contact temperature sensor with fixed point

The invention relates to a touch temperature sensor high measuring accuracy.

Accurate measurements require a calibration of the measuring arrangement, the that is, an experimental determination of the relationship between the value of the output signal and the value of the measurand. To do this, the input of the electrode is connected to a known The measured variable is applied and the assigned measured value output at the output is determined. An electrode consisting of several links can be calibrated in sections and the calibration of the entire electrode is calculated from the results obtained will. The entire electrode can also be calibrated directly in one process. For the complete calibration of a measuring arrangement, that is to say for the inclusion of a Characteristic curve, the input variable is gradually increased or decreased. For the purpose of a simplification of the calibration process can often result in a complete calibration series with gradually changed input values in favor of a few or even just one single calibration value can be dispensed with.

The practical use of a measuring arrangement is often based on the assumption that that the characteristic curve obtained by calibration is valid regardless of time and place is. In fact, this assumption is only approximate. For example, the changes Characteristic curve of a measuring arrangement over time; the measuring arrangement must therefore be in certain Recalibrated at time intervals.

The characteristic curve can also be changed during the measurement process by the action of the measured variable on the transducer or by the action of the environmental parameters on the entire sea level. Occurring during the measurement permanent Changes to the characteristic curve can be made by each calibration can be recognized before and after the measurement.

The considerations generally developed up to now for measurements apply accordingly also for temperature measurements with contact temperature sensors (hereinafter Called BTA). BTAs also have to be calibrated before the measurement and especially with them permanent changes in the characteristic curve can occur during the measurement, which Make calibration before and after measurement desirable. When using common Changes in the characteristic curve that occur during occur during the measurement, but disappear again after the measurement has been completed.

Such an effect occurs in particular when measuring temperature on hot objects by means of BTA, because the ambient temperature is often also here is so high that the properties of temperature-sensitive parts of the electrode (e.g. Supply lines, assemblies such as amplifiers, rectifiers, analog / digital converters, Digital / analog converter, supply voltage equipment, etc.) changed significantly will. In BTA, for example, the change in resistance, a Use inductivity, a capacitance, the natural frequency or a thermoelectric voltage, Changes in the series resistance and the transverse resistance or the transverse capacitance of the supply lines or thermal voltages occur in the supply lines and so systematic Cause measurement errors that are not caused by calibration before and after the measurement are detectable.

Those that only occur during the measurement, mainly due to the environmental parameters Characteristic curve changes caused by temperature and the resulting systematic Measurement errors can also only occur due to a calibration taking place during the measurement process of the entire electrode can be recognized and corrected.

As is well known, an indirect calibration during electrical BTA the measurement take place in such a way that an electrical measurement signal of known magnitude the input of the electrode is given.

In the case of temperature measuring resistors, for example, the calibration signal can be generated by connecting a known resistor in parallel or in series. For thermocouples, the calibration signal can be a known voltage. The principal one The disadvantage of this process is that it is an indirect process acts. It is not a known measured variable that is applied to the transducer, but rather instead, an electrical calibration signal is switched to the electrode. The procedure is also cumbersome because it requires special switching devices. If the BTA and its supply line are not accessible during the measurement, it can at all are not applied or at least it does not include those in the BTA or errors arising in the supply line.

Also known are BTAs that are used to achieve a calibration point Use the "wire method" [1,2] during the measurement. The BTA is a thermocouple cut through the main solder joint and connect by inserting a about 5 mm long wire made of a fixed point material, i.e. a metal whose Melting point is to be used as the fixed temperature point is established. With the The temperature of the object to be measured also rises, and so does the temperature of the thermocouple its thermal voltage until the melting temperature of the connecting wire is reached. The connecting wire begins to melt and pulls itself as a result of the Surface tension into a small ball at the ends of the legs. While the temperature remains constant during the melting process. The disadvantage is that the melting process Due to the small amount of fixed point material, it only takes a few seconds and is inaccurate the rise in temperature can easily be covered, so that for better visibility the melting point a second thermocouple without a fixed point material at the same time must be heated and observed.

The invention described below avoids these disadvantages.

The invention is based on the object of a BTA of high accuracy to build that provides at least one calibration point during the measurement.

According to the invention, therefore, the temperature-sensitive part of the BTA arranged together with a fixed point material in such a way that the thermal resistance RBTA-Fix between the temperature-sensitive part and the fixed point material is low and the thermal resistance Fix mio between fixed point material and measurement object is a multiple of RBTA-Fix.

Fixed point materials are used to represent temperature fixed points. Your transition temperature at the phase transition, for example your melting or Solidification temperature at the phase transition solid / liquid or liquid / solid or theirs Boiling or condensation temperature at the phase transition liquid / gaseous or gaseous / liquid, can be reproduced very precisely. During the phase transition, the fixed point material increases depending on the direction of transition, heats up or gives off heat, but retains its temperature, as long as a two-phase system exists.

Due to the low thermal resistance RBTA-Fix one achieves fiction according to that temperature equalization processes between fixed point material and temperature-sensitive Part quickly expire. With the onset of the phase transition, the temperature-sensitive one also becomes The transformation temperature is applied to the part almost instantaneously.

To make a correction of the measurement curve possible through the calibration point make, according to the invention, the fixed point material is selected so that its transition point lies within the measuring range.

Due to the many times greater thermal resistance Fix mio and the thereby limited heat flow between measurement object and fixed point material achieved a temporal expansion of the phase transition and therefore a good one Marking of the temperature fixed point, i.e. the calibration point as a temperature plateau in the temperature readings supplied by the BTA. For explanation, Figure 1 shows a measurement object temperature assumed to increase linearly in time for the sake of simplicity (Curve 1) the temperature measurement curve 2 supplied by the BTA with the temperature plateau recognizable calibration point shown. Because of the reversibility of the phase transition also occurs when the target temperature decreases over time when the transition temperature is reached in turn a temperature plateau, which can also be used as a calibration point can.

The picture 1 also shows the unwanted caused by Fix mio Side effect that the measured temperature (curve 2) has a time delay A t has compared to the measurement object temperature (curve 1).

t is in the order of magnitude of the time constant t t RFix-Mo (mFix CFix where mF. the mass of the fixed point material and CFix its specific heat is. ß t can be calculated approximately for a given arrangement, so that the Measurement curve can be corrected accordingly.

There are a number of properties for the selection of the fixed point material such as specific heat, heat of transformation, temperature of transformation, handling, machinability, Toxicity and price are important.

A solid mass - meaning solid as opposed to liquid - offers many advantages in handling compared to other aggregate states. According to the invention a solid mass is therefore used as the fixed point material.

Metals generally have the advantage of being easy to machine. They also offer a relatively wide range of transition temperatures. According to the invention therefore metals are used as fixed point material.

By including metal alloys and salts, the spectrum of transition temperatures can be broadened. Therefore be metal alloys and salts are also used according to the invention as fixed point materials.

Liquids in particular enable the representation of fixed points at relatively low temperatures. According to the invention, therefore, they are also as Fixed point materials used.

BTAs should have small dimensions so that they, when installed in objects to be measured, disturb their temperature distribution as little as possible.

Since there are temperature level surfaces in most of the objects to be measured, it is usually sufficient to keep the dimensions of the BTA small in one direction, i.e. that the BTA has a slim shape.

It is arranged in the measurement object that its longitudinal axis is in or approximately lies in a level surface. Since the transverse dimensions of the BTA are significantly affected by the Transverse dimensions of the fixed point material are determined, this should be according to the invention rod-like shape, that is, have elongated shape. So the entire BTA as well gets elongated shape, as well as the temperature-sensitive part and the beginning If the leads are in the longitudinal direction of the fixed point material, they will be in the fixed point material recorded in a longitudinal bore.

For more comfortable handling of the BTA it is necessary to use the fixed point material to be arranged in a container. The container wall forms part of the thermal resistance Fix mio The other part of the thermal resistance is due to the limited thermal conductivity of the part of the measurement object surrounding the container. By appropriate choice A desired RFiX-Mo thermal resistance can be achieved with the holder material. Because of its specific thermal conductivity, its mechanical strength and because of the easy availability and also because of high-temperature applications Due to its temperature resistance, ceramic tubes are particularly suitable as containers. she are therefore used according to the invention.

If so, graphite tubes are chemical resistance and high temperature resistance are required, advantageous. According to the invention, therefore, graphite tubes are used.

Containers are particularly easy to manufacture from metal. In the cases where the thermal resistance of the part of the measuring object surrounding the container is sufficient is large, according to the present invention, the container can be formed from metal.

In some applications there is a risk of a chemical reaction between the fixed point material and the outside atmosphere, be it that the material E.g. copper is very susceptible to oxidation or that the outside atmosphere is very aggressive. In such cases, according to the invention, the fixed point material is covered by covers, for example graphite disks, graphite powder or ceramic masses protected.

In the case of some fixed point materials, there is especially at high temperatures the risk of a reaction with the temperature-sensitive part. To such a reaction To prevent this, a separating layer between the fixed point material must be created in such cases and temperature-sensitive part. This separation can according to the invention can be realized in that the temperature-sensitive part in a thin-walled Ceramic envelope is arranged.

An embodiment of a BTA (total length e = 80mm) with a fixed point for a measuring range from 0 to 1350 OC is shown in Fig. 2. The temperature-sensitive Part is formed by a NiCr-Ni thermocouple. The fixed point material is copper (Melting point 1084.5 OC).

The cylindrical copper body 1 is located in a ceramic tube 2. In the copper body there is a hole in which a ceramic two-hole rod is located 3 for receiving the thermo legs 4 is located. The main solder joint 5 is from one ceramic separating layer 6 (ceramic tube) surrounded. The cover of the ceramic tube 2 is formed by a graphite disc 7 and 8 ceramic putty.

An executed BTA with fixed point material aluminum (melting point 660 OC) was designed similar to that shown in Figure 2.

Because of the lower heat of fusion, only the slenderness was important a little less.

Another exemplary embodiment is shown in Figure 3.

The fixed point material 1 is benzoic acid (melting point 121.7 OC).

The cylindrical container 2 with lid 3 is made of metal.

The temperature sensitive part 4 is made by a NiCr-Ni thermocouple formed, which is attached to the carrier 5 for spatial fixation.

~~~~~ Literature: / 1 / temperature measurement; F. Henning, H. Moser, Berlin, 3rd edition 1977; / 2 / Handbook Techn. Temperature Measurement; PTB 1977, BW 36-11-03.

Claims (14)

Claims. BTA with fixed point, characterized in that the temperature-sensitive part of the BTA arranged together with a fixed point material is that the thermal resistance between the temperature-sensitive part and RBTA-Fix Fixed point material low and the thermal resistance Fix mio between the fixed point material and the DUT is a multiple of RBTA-Fix; 2. BTA with fixed point according to claim 1), characterized in that the transition point of the fixed point material is within the measuring range of the BTA is; 3. BTA with fixed point according to claim 1) to 2), characterized characterized in that a solid mass is used as the fixed point material; 4th BTA with fixed point according to claims 1) to 3), characterized in that the fixed point material a metal is used; 5. BTA with fixed point according to claim 1) to 3), characterized characterized in that a metal alloy is used as the fixed point material; 6th BTA with fixed point according to claims 1) to 3), characterized in that the fixed point material a salt is used; 7. BTA with fixed point according to claim 1) to 2), characterized in that a liquid is used as the fixed point material will; 8. BTA with fixed point according to claim 1) to 7), characterized in that the Fixed point material is rod-shaped and provided with a longitudinal bore, in which the temperature-sensitive part and the beginning of the supply line are arranged; 9. BTA with fixed point according to claim 1) to 8), characterized in that the fixed point material is arranged in a ceramic tube; 10. BTA with fixed point according to claim 1) to 8), characterized in that the fixed point material is arranged in a graphite tube is; 11. BTA with fixed point according to claim 1) to 10), characterized in that the fixed point material is arranged in a metal tube; 12. BTA with fixed point after Claim 1) to 11), characterized in that the fixed point mass by covering is protected against the influences of the outside atmosphere; 13. BTA with fixed point according to claim 1) to 12), characterized in that between the temperature-sensitive part and Fixed point material a separating layer is arranged; 14. BTA with fixed point according to claim 1) to 13), characterized in that the temperature-sensitive part in a Ceramic envelope is arranged.