DE2910957C2 - - Google Patents

Description

The invention relates to an electrical temperature sensor with a small time constant, one of the tempera electrical resistance wire a material with high specific resistance to has direct introduction into the measuring medium, the Resistance wire for the purpose of low inherent resistance and its inherent stability is sufficiently thick and is attached to the input side of a transformer is closed, the low thermometer resistance transformed high resistance.

An electrical temperature sensor of this type is known (F. Lieneweg, manual of technical temperature measurement, 1976, pp. 118, 119), which is used for temperature measurement in boreholes in petroleum extraction. For this purpose, the measuring wire of the known temperature sensor is exposed to the liquid without insulation and the measuring resistor was kept very small so that shunts over the liquid do not falsify the measurement. Therefore, the measuring wire is in the form of at least half a turn up to several turns thick, the thermometer current must be transformed un directly at the measuring point for measuring the resistance, since longer leads can not be allowed because of the very small measuring resistance. Half-lives of 3 × 10 ^-2 seconds can be achieved with the known thermometer or temperature sensor.

Such half-lives or time constants of 3 × 10 ^-2 sec. Are for in situ measurements in sea water, in which the conductivity of the sea water, the temperature and the pressure are to be measured at the same time, with high-speed water flows of up to about 10 m / sec. must be taken into account, completely inadequate, since this value of the known temperature sensor is only insignificantly smaller than the value of the time constant that can be achieved with known temperature sensations (5 × 10 ^-2 sec.) For in situ measurements it is absolutely necessary that in addition to the pressure and the electrical conductivity of the sea water, which can be measured in suitable and known circuits with time constants of 1-2 × 10 ^-3 sec., The temperature of the sea water also with this speed can be measured, which is absolutely necessary in particular for determining the temperature gradients of thin water layers.

The well-known electrical temperature sensor is for the well determined rapid temperature measurements and also not suitable, especially because of the construction of the sensor for in situ measurements in the sea in relation to the formation of the Resistance wire and the way it is attached and  the signal generation on the resistance wire and its ge own processing requirements are set which the known temperature probes because of their different type the use cannot be realized.

It is an object of the present invention to provide an elec trical temperature sensor to create with the temperature measurements in liquid media, for example in the sea water, can be made at a speed can in the order of magnitude of the measuring speed lie in the conductive by means of known measures speed and the pressure of the liquid medium can be measured can and such a great mechanical stability has that the disadvantages of known sensors with extreme small resistance wire diameters, the insulation freely exposed to the medium to be measured and therefore very much are easily destroyed, avoided.

The object is achieved according to the invention that, in order to achieve an extremely small time constant in the range of less than 2 × 10 ^-3 sec., The resistance wire is formed from a metallic material with low heat capacity and a diameter of greater than 10 ^-2 mm, the input side of which is direct is on a branch on a four-pole AC bridge connected to the transformer, which for a subsequent signal amplification, the tap voltage of the resistance wire translates noise-free and that the resistance wire to achieve sufficient mechanical stability in a holding device also serving as a protective cage is stretched out.

The advantage of such a trained electrical temperature sensor lies in the fact that time constants in the range of 5-1 × 10 ^-4 sec. Can actually be reached, which means that the temperature sensor according to the invention achieves constant time by a minimum factor of 60 better time are, whereby the applicant also points out that with the subject of the invention in 1981 even time constants improved by a factor of 300 compared to the cited prior art were achieved, which can be proven at any time, and secondly that due to the formation of the resistance wire and the type of its arrangement guarantees a damage-free and thus reliable measured values producing work in in situ measurements of the sea water.

By providing the transformer, which follows the bridge circuit according to the invention, it is possible that the measuring resistor, which is very small according to the invention, of 1.0 2.0 × 10 ^-2 ohms allows its resistance change to be measured directly with the AC bridge when the temperature changes , because active amplifier elements can now be connected to the transformer on the secondary side, the input noise of which need not be below the values of those which are available at present in such signal amplifiers.

The resistance wire made of a metallic material with Training low heat capacity supports advantage unfortunately the reaching of the extremely small time constant.

The invention will now be described with reference to the following drawings based on several embodiments described in detail. In it show:

Fig. 1 a temperature sensor with a temperature-measuring electric resistance wire,

Fig. 2 and 3, a temperature sensor wherein the electrical resistance wire is disposed sensor at different locations between incoming and outgoing lines for temperature and

Fig. 4 shows the exemplary structure of a measuring circuit arrangement in which the temperature sensor is arranged.

As a temperature sensor with an extremely small time constant, a stable resistance wire 1 with a large cross-section and a short length is used, which is basically uninsulated, ie bare or slightly insulated from the measuring medium.

Because of the very small remaining resistance value of the resistance wire 1 in this case, for example 1-2 × 10 ^-2 ohms, its resistance value changes depending on the temperature cannot be measured directly with a bridge circuit, since sufficiently low-noise active amplifier elements are not available.

It is therefore used in connection with FIG. 4 AC bridge circuit to be described in more detail in the form of a known two-phase bridge circuit (German patent 22 05 989) and in a series circuit a comparison resistor and the resistance wire 1 as a temperature sensor in the same bridge branch over suitably dimensioned and in their resistance - and the phase response behave electrically matched transformers inserted. These transformers allow a noise-free voltage translation of the tap voltages from the comparison resistor and the resistance wire 1 .

Referring to FIG. 1, the resistance wire 1 between electrical connection points 2 and 5 between two compared to the resistive wire stronger formed lead wires 8, and a current feedback bracket 6, 7 is clamped. The preferably amplitude-constant measuring alternating current, which enters in the direction of the arrow at point 5 and exits again at point 2 , causes a measuring alternating voltage at the tapping points 3 and 4 , which are connected via connections 9 and 10 to primary terminals 11 and 12 of the thermometer transformer. This voltage is therefore highly amplified at the outputs 13 and 14 of the thermometer transformer. The tap points 3 and 4 are slightly away from the supply points 2 and 5 . They prevent temperature flow to the lead wires and points. The resistance wire 1, which can be a platinum wire, for example, is dimensioned such that it has a sufficiently small resistance even when it is immersed directly in the sea in order to be able to exclude influences of the electrical tributary flow from the sea water on the resistance wire and thus on the temperature measurement. In contrast, the input impedance of the primary side of the thermometer transformer is dimensioned sufficiently large so that the measuring current which flows into the temperature sensor at point 8 is essentially kept away from the primary winding of the thermometer transformer in order to keep the effects on the induction of the transformer material small.

In FIGS. 2 and 3 by way of example, further embodiments are shown of the temperature sensor, the details are partially omitted. According to the embodiments of FIGS. 2 and 3, all feed and discharge lines take place from one side via points 8 and 7 and the taps from points 3 and 4 via points 9 and 10 . The cylinder 15 shown in FIGS. 2 and 3, which is provided with many openings, forms a protective cage for the resistance wire 1 and at the same time forms a holding device. In the embodiment according to FIG . 3, the resistance wire 1 is designed as a loop, which is kept insulated by a hook 16 at point 17 . The cylinder 15 can also be made of non-metal.

A transformer generally affects the phase relationship in an AC bridge circuit. For this reason, the comparison resistance to the resistance wire 1 is also on the primary side of a practically electrically identical transformer 21 , cf. Fig. 4, connected. The two transformers 21 and 22 are located at the taps of the bridge members 20 and 24 connected in series in a bridge branch 23 . They are fed from a source 18 via point 19 with a constant current, which is controlled via point 25 from a source 26 with an alternating voltage. A control resistor 27 is used to adjust the transformer 21 to the properties of the transformer 22 . Other known circuits can also be used for this. The transformer 22 is connected to the resistance wire 1 . In a circuit part 32 , the voltages of the transformers 21 and 22 are added or subtracted according to the two-phase bridge, higher-frequency interference signals are damped in a low-pass filter and added in a circuit arrangement 29 with the 90 ° phase-shifted voltage from a further voltage source, so that on An alternating voltage is available at output 30 , the phase change of which, for example, compared to the phase of the alternating current through the bridge branch, which consists of the series connection of 20 and 24 mentioned above, is a measure of the temperature change at the temperature sensor. Which is traversed by the constant alternating current in conjunction with the transformers 21 and 22 of the bridge arm of FIG. 4, can be inserted according to the principle of the invention also in other alternating-current power bridges. The realization of the principle according to the invention is therefore not limited to the two-phase bridge circuit described above.

With the electrical temperature sensor there is also no restriction that a transformer is connected to each of these resistors in the bridge branch of the comparison and resistance wire 1 . Such happens preferably because in this case, for example, temperature-related changes in the transformer properties compensate. In principle, however, the comparison resistor can be dimensioned such that the voltages that can be tapped across it are so high that the transformer 21 can be dispensed with. In this case, however, a circuit must be provided in the tap voltage circuit, which imitates the transformer 21 with respect to the amplitude and phase behavior, which can be achieved by known methods.

Claims (10)

1. Electrical temperature sensor with a small time constant, which has a temperature measurement electrical resistance wire made of a material with a large speci fi c resistance for direct introduction into the measuring medium, the resistance wire being thick for the purpose of low inherent resistance and its inherent stability and to the input side of a Transformer is connected, which transforms the low thermometer resistance up to high resistance, characterized in that to achieve an extremely small time constant in the range of less than 2 × 10 ^-3 sec. The resistance wire ( 1 ) made of a metallic material with a low heat capacity a diameter of greater than 10 ^-2 mm is formed, the input side ( 4 , 5 ) is located directly in a branch of an AC bridge formed as a four-pole, which is connected to the transformer, which for a subsequent signal amplification, the tap voltage of the counter stands wire translated noise-free and that the resistance wire ( 1 ) is stretched to achieve sufficient mechanical stability in a holding device ( 15 ) also serving as a protective cage. 2. Temperature sensor according to claim 1, characterized in that the resistance wire ( 1 ) in an AC bridge ( 18 , 19 , 20 , 24 ), the comparison branches of which have a phase shift of 90 ° relative to one another, with a comparison resistor ( 20 ) connected in series is, which is preferably flowed through with an alternating current with a constant amplitude, the voltages of the bridge branches with the comparison resistor ( 20 ) and the resistance wire ( 1 ) having essentially no phase angle deviating from 0 ° or 180 ° by controllable phase control elements. 3. Temperature sensor according to claim 2, characterized in that for substantially noise-free amplification, the tapping voltage from the comparative resistor ( 20 ) and resistance wire ( 1 ) are each removed via a transformer ( 21 , 22 ) through which the temperature-related voltage changes across the comparative resistor ( 20 ) and the resistance wire ( 1 ) are amplified without noise. 4. Temperature sensor according to one of claims 1 to 3, characterized in that the measuring voltage at two measuring voltage supply points to avoid heat line influences distant taps on the resistance wire ( 1 ) via connecting wires made of the same material and the primary side ( 11 , 12 ) of the transformer ( 22 ) is supplied. 5. Temperature sensor according to one of claims 2 to 4, characterized in that to reduce a secondary current to the resistance wire through the primary side ( 11 , 12 ) of at least one transformer ( 22 ) whose primary input impedance is significantly higher than that of the comparison resistor ( 20 ) and the resistance wire ( 1 ) lies. 6. Temperature sensor according to one of claims 2 to 5, characterized in that the transformers ( 21 , 22 ) of the comparison resistor ( 20 ) and the resistance wire ( 1 ) are designed such that their temperature-related phase changes can be compensated. 7. Temperature sensor according to claim 6, characterized in that the compensation on the transformer ( 21 ), in the primary circuit of which the comparison resistor ( 20 ) is connected, can be carried out. 8. Temperature sensor according to claim 7, characterized in that the compensation of the transformer ( 21 ) is controllable. 9. Temperature sensor according to one of claims 2 to 8, characterized in that a phase shift caused by the transformers ( 21 , 22 ) with respect to the phase of the input voltage to the bridge arm by an addition voltage, which is shifted from the and the phase shifted AC voltage by 90 ° Alternating current bridge ( 18 , 19 , 20 , 24 ) can be obtained, compensation is bar. 10. Temperature sensor according to one of claims 7 to 9, characterized in that a compensation of the pressure dependency of the resistance wire ( 1 ) in the tap voltage circuit of the comparison resistor ( 20 ) is feasible.