EP4367490A1 - Thermometer with improved measurement accuracy - Google Patents

Abstract

The invention relates to a device (1) and a method for determining and/or monitoring at least the temperature (T) of a medium (M) in a container (2), the device comprising: - a first temperature sensor (6) for measuring the temperature (T); and - a heating/cooling element (8) for heating/cooling a specifiable region (B) of the device (1), in which region (B) in particular at least the first temperature sensor (6) is located. According to the invention, the first temperature sensor (6) and the heating/cooling element (8) are arranged such that, when the device (1) is arranged on/in the container, a distance (d₁) of the first temperature sensor (6) from a center (Z) of the container (2) is less than a distance (d₂) of the heating/cooling element (8) from the center (Z).

Description

Thermometer with improved measurement accuracy

The invention relates to a device for determining and/or monitoring at least the temperature, the flow rate or the flow rate of a medium in a container, for example in automation technology. The container is, for example, a container or a pipeline.

Thermometers have become known in a wide variety of configurations from the prior art. There are thermometers that use the expansion of a liquid, a gas or a solid with a known coefficient of expansion to measure the temperature, or those that relate the electrical conductivity of a material or a quantity derived from it to the temperature, such as the electrical resistance when using resistance elements or the thermoelectric effect in the case of thermocouples. In contrast, radiation thermometers, especially pyrometers, use the thermal radiation of a substance to determine its temperature. The measurement principles on which they are based have each been described in a large number of publications. In the case of a temperature sensor in the form of a resistance element, so-called thin-film and thick-film sensors and so-called thermistors (also referred to as NTC thermistors) have become known, among other things. In the case of a thin-film sensor, in particular a resistance temperature detector (RTD), a sensor element provided with connecting wires and applied to a carrier substrate is used, for example, with the rear side of the carrier substrate usually being metallically coated. So-called resistance elements, which are provided for example by platinum elements, are used as sensor elements, which are also commercially available under the designations PT10, PT100 and PT1000, among others.

In the case of temperature sensors in the form of thermocouples, on the other hand, the temperature is determined by a thermal voltage that arises between the thermowires made of different materials and connected on one side. Thermocouples according to DIN standard IEC584, e.g. thermocouples of type K, J, N, S, R, B, T or E, are usually used as temperature sensors for temperature measurement. However, other pairs of materials, in particular those with a measurable Seebeck effect, are also possible.

The accuracy of the temperature measurement depends sensitively on the respective thermal contacts and the prevailing heat conduction. The heat flows between the medium, the container in which the medium located, the thermometer and the process environment play a crucial role here. For a reliable temperature determination, it is important that the temperature sensor and the medium are essentially in thermal equilibrium, at least for a specific time that is required to detect the temperature. The time it takes for a thermometer to respond to a change in temperature is also known as the thermometer's response time.

A high measurement accuracy can be achieved in particular when the temperature sensor is immersed in the respective medium. Numerous thermometers have become known in which the temperature sensor is brought into contact more or less directly with the respective medium. In this way, a comparatively good coupling between the medium and the temperature sensor can be achieved, and temperature gradients between the temperature of the medium and the temperature in the immediate vicinity of the temperature sensor are comparatively small.

However, a non-invasive determination of the temperature is advantageous for various processes and for many containers, in particular small containers or pipelines. Thus, thermometers have also become known which can be attached to the respective container in which the medium is located and in which the temperature sensor only comes into indirect contact with the medium. Such devices, also known as surface thermometers or contact sensors, are disclosed, for example, in DE102014118206A1 or DE102015113237A1. To ensure good thermal coupling, various additional aspects must then be taken into account, such as good mechanical and therefore also thermal contact between the container and the thermometer. If there is insufficient contact, an accurate temperature determination is not possible. A central problem in non-invasive temperature determination is therefore generally the heat dissipation from the process to the environment. This may result in a significantly higher measurement error than in the case of a direct introduction of the respective temperature sensor into the process.

A similar set of problems also arises, for example, in the case of a flow meter based on the thermal measurement principle for determining a flow rate or a flow rate of a medium in a pipeline. Such field devices typically include at least two sensor elements with at least one temperature sensor and at least one heating element or heatable temperature sensor. The sensor elements can be introduced into the respective pipeline as well as integrated into or onto a measuring tube (non-invasive construction). Based on the described problems of heat dissipation in the measurement accuracy of temperature sensors, the invention is based on the object of providing a possibility for temperature determination, in particular for thermometers and measuring devices for determining a flow rate or a flow rate, which is characterized by high measurement accuracy.

This object is achieved by the device for determining and/or monitoring at least the temperature of a medium in a container, comprising a first temperature sensor for detecting the temperature, and a heating/cooling element for heating/cooling a predetermined area of the device in which Area is at least the first temperature sensor.

According to the invention, the first temperature sensor and the heating/cooling element are arranged such that when the device is arranged on/in the container, the distance between the first temperature sensor and a center of the container is smaller than the distance between the heating/cooling element and the center. The heating/cooling element is therefore arranged closer to the environment than the temperature sensor. The container is, for example, a container or a pipeline. Depending on the design of the container, the center can either be a center point of the container, for example in the case of a container, or a central axis in the container, for example in the case of a pipeline.

The device can optionally also have electronics, for example a transmitter. Alternatively, the electronics can also be a separate component that can be connected to the device. In particular, it is also possible to use a device according to the invention with 4-20 mA electronics or a 4-20 mA transmitter. Accordingly, the device can also be designed as a two-wire field device.

In addition, depending on the design, the device can also include other components, for example fastening means for fastening individual components to a wall of the container, or in the case of an invasive thermometer, a protective tube. In particular, it is also possible to use a device according to the invention

By means of the heating/cooling element, the effects of heat conduction between the medium and the environment, ie a temperature gradient that occurs, can be weakened or minimized. A temperature gradient always occurs when the temperature of the medium differs from the temperature of the environment surrounding the device, in particular the first temperature sensor. The greater the difference between these two temperatures, the steeper the temperature gradient and the larger the resulting measurement error. A temperature gradient occurring in the region of the temperature sensor can be compensated for by means of the heating/cooling element. The avoidance of so-called heat conduction errors is a fundamental endeavor in the field of industrial temperature determination, regardless of whether a thermometer or a flow meter is used. In the case of invasive thermometers, the so-called minimum immersion depth in the respective process is often mentioned in this context, which should usually be at least ten times the diameter of the thermometer. If the thermal contact has deteriorated, for example through the use of a protective tube, the minimum immersion depth should be more than ten times the diameter of the thermometer. In the case of block calibrators, the minimum immersion depth is usually fifteen times the diameter of the reference thermometer used for calibration. In the case of non-invasive temperature determination, on the other hand, other measures must be taken to ensure homogeneous temperature control of the respective sensor element. However, due to the very inhomogeneous heat input in such a measurement, this is significantly more complex than in the case of an invasive temperature determination.

The device according to the invention can be either an invasive or a non-invasive device. In an invasive device in which the first temperature sensor is immersed in the medium, the heating/cooling element is preferably arranged at a definable distance from the first temperature sensor and its position has a smaller distance or a smaller distance from a wall of the container. In the case of a non-invasive device, the first temperature sensor is preferably arranged between the container and the heating/cooling element when the device is in a state attached to the container, and the first temperature sensor is preferably arranged on the wall of the container.

One configuration includes that the first temperature sensor is a resistance element, a thermocouple or a thermistor.

A further configuration includes that the heating/cooling element is a resistance element, a Peltier element, a foil heating element or an inductive heating element.

It is also advantageous if the device comprises at least one reference element for in situ calibration and/or validation of at least the first temperature sensor, which is attached in particular to a carrier element, and which Reference element consists at least partially of at least one material, for which material at least one phase transition occurs at least in the temperature range relevant for calibrating the first temperature sensor at least at a predetermined phase transition temperature, for which phase transition the material remains in the solid phase. In this regard, reference is made to EP02612122B1, to which reference is made in its entirety.

In one configuration of the device, the first temperature sensor and the heating/cooling element are arranged in a common measuring insert. In this case, the first temperature sensor is preferably arranged in an end region of the measuring insert. The heating/cooling element is preferably arranged in a central area of the measuring insert. At least the first temperature sensor is preferably located between the end region and the heating/cooling element. However, numerous other configurations for the arrangement of at least the first temperature sensor and the heating/cooling element are also conceivable, which also fall under the present invention. For example, an alternative configuration for a device according to the invention includes that the first temperature sensor is arranged in a measuring insert and that the heating/cooling element is arranged outside of the measuring insert, in particular from the outside on the measuring insert or on a protective tube into which the measuring insert can be inserted. attachable, is. The first temperature sensor is accordingly placed in a measuring insert, in particular a measuring insert according to the prior art. The heating/cooling element is arranged outside of the measuring insert. For example, the heating/cooling element can be applied to the measuring insert from the outside. However, it can also be placed in a protective tube of the device, into which the measuring insert can be introduced.

It is also advantageous if at least the heating/cooling element is arranged in a housing. The housing can be, for example, a sleeve that can be fastened to the measuring insert, or an additional measuring insert for accommodating the heating/cooling element.

In a further refinement, the device comprises a second temperature sensor which is arranged at a definable distance from the first temperature sensor. The second temperature sensor is preferably used

Determination of a temperature gradient, which is caused by heat conduction from the process to the environment or vice versa. A temperature gradient in the region of the first temperature sensor can therefore preferably be determined on the basis of a difference between the temperatures determined by means of the two temperature sensors. The first and second temperature sensors can be arranged together in a measuring insert, possibly also together with the heating/cooling element. However, it is also conceivable for the temperature sensors and/or the heating/cooling element to be arranged at least partially separately from one another. If the heating/cooling element is arranged in a housing, for example, the second temperature sensor can also be arranged in the housing, in a measuring insert for the first temperature sensor, or separately from the first temperature sensor and the housing.

One configuration includes that the first temperature sensor comprises a temperature-sensitive sensor element, which is electrically contacted via at least a first and a second connection line, wherein the first connection line is divided into a first and a second section, the first section facing the sensor element consisting of a first material, and wherein the second section facing away from the sensor element consists of a second material that differs from the first material, the second connection line consists of the second material, and the first section of the first connection line and at least part of the second connection line have a difference -Form temperature sensor in the form of a thermocouple. In this context, reference is made to DE102018116309A1, to which reference is also made in full within the scope of the present application. With such a configuration of the temperature sensor, it is possible to directly and immediately detect heat dissipation in the area of the temperature sensor. Accurate knowledge of the heat dissipation further increases the measurement accuracy of the device.

Furthermore, in one embodiment, the device according to the invention comprises a regulation/control unit for regulating or controlling the heating/cooling unit by means of an adjustable heating/cooling signal. The regulation/control unit can, for example, be part of the electronics or also a separate component of the device.

In a further configuration, the device comprises a unit comprising at least partially a material with anisotropic thermal conductivity, which is arranged and/or designed in particular in such a way that it at least partially surrounds at least the first temperature sensor. In this context, reference is made to the German patent application with the file number DE102017100267A1, to which reference is made in its entirety within the scope of the present invention.

It is also advantageous if the device includes or has a coupling element for attachment to the container. The coupling element comprises a base body with a contact surface, which is designed such that the base body by means of Contact surface can be placed flat against the container, wherein the base body has a bore for receiving at least the first temperature sensor, and wherein a longitudinal axis of the bore runs tangentially to the contact surface. With regard to the coupling element, reference is again made to the previously unpublished German patent application with the file number 102021109410.0. This patent application is also referred to in its entirety.

With regard to the coupling element, one embodiment of the device according to the invention includes that the heating/cooling element is at least partially introduced or integrated into the coupling element. The heating/cooling element is preferably introduced into an area of the coupling element which, when the coupling element is in the state attached to the container, is at a greater distance from the container than the first temperature sensor. The object on which the invention is based is also achieved by a method for determining and/or monitoring the temperature using a device according to the invention, comprising the following method steps:

detecting a temperature of the medium by means of a first temperature sensor, and - heating or cooling a predetermined area of the device, in which

Area where at least the first temperature sensor is located by means of a heating/cooling unit.

In one embodiment of the method according to the invention, a heating/cooling signal for the heating/cooling element is selected in such a way that a temperature gradient in the predefinable range is minimized. In particular, it is a temperature gradient that occurs due to different temperatures of the medium and the environment. The heating/cooling signal is preferably selected in such a way that an essentially constant temperature prevails in the predefinable range.

It is advantageous if the heating/cooling element is regulated or controlled by means of an adjustable heating/cooling signal. In this case, it is an adjustable heating/cooling signal that can be adapted in particular to the respective conditions in the environment of the device.

It is also advantageous if the heating/cooling signal is set as a function of a differential temperature value determined by means of the first and second temperature sensors or by means of the differential temperature sensor. The differential temperature value can be either an absolute or a relative temperature difference. Finally, it is also advantageous if the heating/cooling signal is adjusted in such a way that the differential temperature value determined by means of the first and second temperature sensors or by means of the differential temperature sensor is minimized, ie in particular approaches zero or is essentially zero.

The device can be, for example, a thermometer or a thermal flow meter. In the case of a thermal flow meter, on the one hand, the heating/cooling element can also be used to determine the flow, which can be either a volume flow or a mass flow. Alternatively, the device can also have an additional heating element, which can be used to determine the flow or the flow rate.

In the case of thermal flow meters, the flow or the flow rate can in principle be determined in two different ways. According to a first measuring principle, a sensor element is heated in such a way that its temperature remains essentially constant. If the medium properties are known and at least temporarily constant, such as the medium temperature, its density or composition, the mass flow rate of the medium through the pipeline can be determined using the heating power required to keep the temperature at the constant value. The temperature of the medium is understood to mean that temperature which the medium has without an additional heat input from a heating element. With the second measuring principle, on the other hand, the heating element is operated with constant heating power and the temperature of the medium is measured downstream of the heating element. In this case, the measured temperature of the medium provides information about the mass flow. In addition, however, other measuring principles have also become known, for example so-called transient methods in which the heating power or the temperature are modulated. It should be pointed out that the configurations described in connection with the device according to the invention can also be applied mutatis mutandis to the method according to the invention and vice versa.

The invention is explained in more detail on the basis of the following figures. It shows:

1 shows a thermometer for (a) non-invasive temperature measurement, (b) a schematic representation of the heat dissipation that occurs, and a thermometer for (c) invasive temperature measurement according to the prior art; 2: preferred configurations for a thermometer according to the present invention with a first temperature sensor and a heating/cooling element, with (a) the first temperature sensor and the heating/cooling element being arranged together in a measuring insert and (b) being arranged separately from one another;

3 shows preferred configurations for a thermometer according to the invention with two temperature sensors, with (a) the first temperature sensor and the heating/cooling element being arranged together in a measuring insert and (b) being arranged separately from one another; 4: exemplary embodiment of a thermometer with a differential temperature sensor for determining the heat flow; and

5: preferred configurations for a device according to the invention in the form of a thermal flow meter.

In the figures, the same elements are provided with the same reference numbers.

The configurations from the various figures can also be combined with one another as desired. The following description relates to thermometers without loss of generality. The respective considerations can easily be transferred to other types of field devices, such as thermal flowmeters.

1a shows a schematic representation of a thermometer 1 according to the prior art for detecting the temperature T of a medium M in a container 2 in the form of a pipeline. In the present case, the thermometer 1 does not protrude into the pipeline 2, but rather is placed on a wall W of the pipeline 2 from the outside for non-invasive temperature determination. The thermometer 1 includes a measuring insert 4 and electronics 7. The measuring insert includes a temperature sensor 6, which in the present case is provided by a temperature-sensitive element in the form of a resistance element. The temperature sensor 5 is electrically contacted via the connection lines 4 and connected to the electronics 7 . While the thermometer 1 shown is designed in a compact design with integrated electronics 7, in other thermometers 1, the

Electronics 7 can also be arranged separately from the measuring insert 4. Also, the temperature sensor 6 does not necessarily have to be a resistance element and the number of connection lines 4 used does not necessarily have to be two. Rather, the number of connecting lines 4 depending be selected appropriately according to the applied measuring principle and the temperature sensor 6 used.

As already explained, the measuring accuracy of such a thermometer 1 depends to a large extent on the heat conduction effects and possibly existing temperature gradients DT between the medium M and an environment of the thermometer 1 . The occurrence of such temperature gradients AT(d) is illustrated as an example in FIG. 1b as a function of the distance d from the medium M.

The medium M has the temperature TM, which is higher than the ambient temperature Tu for the analysis carried out the temperature of the medium TM. A heat loss also typically occurs between the wall and the thermometer 1 , which continues up to the electronics 7 . The temperature T recorded by means of a contact sensor 1 is usually lower than the actual temperature of the medium TM.

Similar problems can also arise for invasively working devices 1 for temperature determination, such as the one sketched in FIG. 1c, which, in contrast to the thermometer 1 shown in FIG. 1a, also has an optional protective tube 3 protruding into the medium M for receiving the measuring insert 4 has.

In order to counteract these problems in a suitable manner, a heating/cooling element 8 is additionally integrated within the scope of the present invention. Two preferred configurations for a thermometer 1 according to the invention are illustrated in FIG. In addition to the thermometer 1 shown in FIG. 1a, the thermometer 1 according to FIG.

The first temperature sensor 6 thus has a first distance di from a center Z in the form of a central axis (longitudinal axis through the pipeline 2 through a center point of its cross-sectional area, which is circular in this case), which is less than a distance d2 of the heating/cooling element from the center Z. In this way, a predeterminable area B of the device 1, in which at least the first temperature sensor 6 is located, can be suitably heated/cooled by means of the heating/cooling element 8, such that a temperature gradient DT in this area B is reduced or eliminated can. In the embodiment shown in FIG. 2b, in contrast to the embodiment according to FIG. 2a, the heating/cooling element is arranged outside of the measuring insert 4. Here is the heating / cooling element 8 in a housing 18a in the form of a sleeve, which the measuring insert 4 can be fastened around, and thus surrounds the measuring insert 4. Here, too, a distance d2 of the heating/cooling element 8 from the center Z is greater than a distance di from the first temperature sensor 6 from the center. Alternatively, the heating/cooling element 8 can also be attached to an inner wall of the protective tube 3, for example, or it can be arranged in a completely different way. The heating / cooling unit 8 can have the same electronics? be contacted like the first temperature sensor 6 or separate electronics [not shown].

It should be pointed out that in addition to the configurations shown here, other configurations of the device 1 and relative arrangements of the device 1 to the container 2 are also possible and fall within the scope of the invention. In particular, a longitudinal axis of the device 1 , in particular of the measuring insert 3 , can also be aligned at an angle other than 90°, in particular parallel, to the wall of the container 2 or the longitudinal axis through the container 2 .

In the embodiment according to FIG. 3, the device 1 additionally includes a second temperature sensor 10, which is also contacted via two connecting lines 11, for example, and which is arranged above and at a definable distance d _ß from the first temperature sensor 6, i.e. in the When the device 1 is arranged in the container, it is at a greater distance from the center Z than the first temperature sensor 6. For the exemplary embodiment shown in FIG. 3a, in which both temperature sensors 6, 10 and the heating/cooling element 8 are arranged together in a measuring insert 4 , the distances of the heating/cooling element 8 and the second temperature sensor 10 from the center Z are essentially the same. In other configurations, the two temperature sensors 6, 10 and the heating/cooling element 8 can also be arranged differently relative to one another.

In the embodiment shown in FIG. 3 b , the second temperature sensor 10 and the heating/cooling element 8 are arranged outside of the measuring insert 4 for the first temperature sensor 6 . For the variant shown here, the second temperature sensor 8 and the heating/cooling element 8 are also located in a housing 18b, here in the form of a further measuring insert. Alternatively, for example, an arrangement analogous to the configuration according to FIG. 2b is also possible here.

In addition or as an alternative, it is also conceivable to design the first 6 and/or second temperature sensor 10 in such a way that a differential temperature sensor is formed by means of the connection lines, as illustrated in FIG. 4 using two possible designs. A temperature sensor 6 in the form of a resistance element 13 applied to a substrate 12 is used to determine and/or monitor the temperature T of the medium M. The temperature sensor 6 is Connection lines 5a and 5b electrically contacted and is thus operated in the so-called two-wire circuit. In the present case, both connection lines 5a and 5b are attached directly to the resistance element 13. FIG. However, it should be pointed out at this point that in principle all contacts known to those skilled in the art are possible for connecting the temperature sensor 6 to the connecting lines 5 .

The first connection line 5a is divided into a first section I and a second section II. The first section I consists of a first material, and the second section II and the second connection line 5b consist of a second material that differs from the first. In this way, the first section I of the first connecting line 5a and at least part t of the second connecting line 5b form a first differential temperature sensor 14 in the form of a thermocouple. The two materials for the first section I of the first connecting line 5a and the second section II of the first connecting line 5a and for the second connecting line 5b are selected in such a way that due to a temperature difference between points a and b and the corresponding due to the thermoelectric effect in the sections t forming different thermal voltages, by means of the differential temperature sensor 14, a thermal voltage can be detected. The first section I of the first connecting line 5a is preferably short compared to the overall length of the first connecting line 5a, for example the length of the first section I of the first connecting line 5a is in the range of a few millimeters or centimeters. In this way it can be ensured that the values determined by means of the first differential temperature sensor 14 reflect a temperature gradient DTi in the region of the temperature sensor 6 as far as possible.

In the example shown in FIG. 4a, the first 5a and second connection line 5b are attached separately to the resistance element 13. FIG. The first section I of the first connection line 5a and the part t of the second connection line 5b are therefore connected indirectly via the resistance element 13 . In another embodiment, however, the first section I of the first connection line 5a and the part t of the second connection line 5b could also be connected directly to one another and then attached to the temperature sensor 6 . In the embodiment shown in FIG. 4b, the second connection line 5b is also divided into a first III and a second section IV. In this case, the first differential temperature sensor 14 is formed by the first sections I and III of the first 5a and second 5b connection lines. According to FIG. 4b, but not necessarily, the two first sections I and III of the two connection lines 4a and 4b are of the same length. In the second sections II and IV of the first 4a and second 4b connection lines in this case, extension wires are preferably of the same design. However, even in the case of the configuration according to FIG. 4a, it is advantageous if the second section II of the first connecting line 5a and the second connecting line 5b are configured in the same way.

A heat flow W in the area of the temperature sensor 6 can be determined by means of the differential temperature sensor 14, which is directly related to an occurring temperature gradient DT. Both by means of configurations of the device according to the invention with at least one second temperature sensor 10 and with a differential temperature sensor 14, occurring temperature gradients in the definable range B can accordingly be determined experimentally directly. In this case, a heating/cooling signal for the heating/cooling element 8 can be appropriately controlled so that these temperature gradients DT are reduced or eliminated. This procedure improves the measuring accuracy of the device considerably. Alternatively, however, it is also possible to determine or estimate the temperature gradient using a formula or stored reference curves.

Finally, FIG. 5 relates to two devices 1 according to the invention in the form of thermal flowmeters. FIG. 5a shows a thermal flow measuring device 1 which, analogously to the device 1 in the form of a thermometer from FIG. the number can vary from configuration to configuration], a heating/cooling element 8 with connection lines 9 . In addition, a heating unit 15 is also provided, which is electrically contacted via the connecting lines 16 . The heating/cooling element 8 is used to reduce or eliminate the influence of undesired heat conduction, while the heating unit 15 can be determined to determine the flow rate or a flow rate according to the thermal measurement principle already explained. Even if FIG. 5a relates to a non-invasive configuration of the device 1, such a configuration can serve both for an invasive and a non-invasive determination of the flow rate, in particular a volume or mass flow rate, or the flow rate. Optionally, the device 1 can also have thermal insulation 16, which thermally shields the device 1, at least the first temperature sensor 6 and the heating unit 15, from the environment.

While in the embodiment shown in FIG. 5a a longitudinal axis Lv of the device 1 runs perpendicularly to a longitudinal axis LB of the container 2, in the case of FIG. 5b the longitudinal axis Lv of the device 1 is aligned parallel to the longitudinal axis LB of the container 2 .

Devices 1 in the form of thermal flow meters can also have a second temperature sensor 10 or a differential

Temperature sensor 14 have. It is then advantageous if a heating signal for the heating/cooling element remains constant during the acquisition of measured values for determining the flow or the flow rate. In particular, it is advantageous if a suitable heating/cooling signal for the heating/cooling element is determined in a first operating mode, for example as a function of a differential temperature value determined by means of first 6 and second temperature sensors 10 or by means of differential temperature sensor 14. In this regard, it is particularly advantageous if the heating unit 16 remains unheated during the first operating mode. In a second operating mode, the heating/cooling signal for the heating/cooling element is then preferably kept constant.

In summary, the device according to the invention can be used to ensure that only little heat is dissipated to the environment via the measuring insert 4 . The definable area B, in which at least the first temperature sensor 6 and at least a section of the connecting lines 5 and, if applicable, the heating element 15 and a section of the connecting lines 16 are located, is suitably heated/cooled, in particular in such a way that a temperature gradient DT in this Area is reduced or minimized, measurement errors caused by this due to heat dissipation can be minimized.

If a second temperature sensor 10 or a differential temperature sensor 14 is used, a simple control circuit can be provided, by means of which a heating/cooling signal for the heating/cooling element is generated depending on a differential temperature of the differential temperature sensor 14 or a temperature difference between the first 6 and second temperature sensor 10 can be adjusted.

reference list

1 device

2 container 3 protective tube

4 measuring insert

5 connection lines for the first temperature sensor

6 First temperature sensor

7 electronics 8 heating/cooling element

9 connection lines heating/cooling element

10 Second temperature sensor

11 connection lines of second temperature sensor

12 substrate 13 resistive element

14 differential temperature sensor

15 heating unit

16 connection lines heating/cooling element

17 insulation 18 housing for heating/cooling element; 18a in the form of a cuff; 18b in the form of a further measuring insert

M medium

T temperature W wall of the container

B predeterminable area of the device

Z Center of the container d Distances between the temperature sensors, the heating/cooling element and the

Center DT Temperature gradient l,ll Sections of the connection lines

L longitudinal axis

Claims

patent claims

1 . Device (1) for determining and/or monitoring at least the temperature (T) of a medium (M) in a container (2), comprising: a first temperature sensor (6) for detecting the temperature (T), and a heating/cooling element (8) for heating/cooling a predeterminable area (B) of the device (1), in which area (B) in particular at least the first temperature sensor (6) is located; characterized in that the first temperature sensor (6) and the heating/cooling element (8) are arranged in such a way that when the device (1) is arranged on/in the container, a distance (di) of the first temperature sensor (6) from a Center (Z) of the container (2) is smaller than a distance (d2) of the heating / cooling element (8) from the center (Z).

2. The device (1) according to at least one of the preceding claims, comprising at least one reference element for in situ calibration and/or validation of at least the first temperature sensor (6), which is attached in particular to the carrier element, and which reference element at least partially consists of at least one Material exists, for which material at least one phase transition occurs at least in the temperature range relevant for the calibration of the first temperature sensor (6) at at least one predetermined phase transition temperature, for which phase transition the material remains in the solid phase.

3. Device (1) according to at least one of the preceding claims, wherein the first temperature sensor (6) and the heating/cooling element (8) are arranged in a common measuring insert (4).

4. Device (1) according to at least one of the claims, wherein the first temperature sensor (6) is arranged in a measuring insert (4), and wherein the heating/cooling element (8) is arranged outside of the measuring insert (4), in particular from the outside can be fastened to the measuring insert (4) or to a protective tube into which the measuring insert (4) can be introduced.

5. Device (1) according to claim 4, wherein at least the heating-cooling element is arranged in a housing.

6. Device (1) according to at least one of the preceding claims, comprising a second temperature sensor (10) which is arranged at a predetermined distance (d _ß ) from the first temperature sensor (6).

7. Device (1) according to at least one of the preceding claims, wherein the first temperature sensor (6) comprises a temperature-sensitive sensor element (13), which is electrically contacted via at least a first (5a) and a second (5b) connecting line, wherein the first connecting line (5a) is divided into a first and a second section, the first section facing the sensor element (13) consisting of a first material, and the second section facing away from the sensor element (13) consisting of a second different material from the first material, the second connecting line (5b) being made of the second material, and the first section of the first connecting line (5a) and at least part of the second connecting line (5b) forming a differential temperature sensor (14) in the form of a thermocouple.

8. Device (1) according to at least one of the preceding claims, comprising a regulation/control unit (15) for regulating or controlling the heating/cooling element (8) by means of an adjustable heating/cooling signal.

9. Device (1) according to at least one of the preceding claims, with a unit comprising at least partially a material with anisotropic thermal conductivity, which is arranged and/or designed in particular in such a way that it at least partially surrounds at least the first temperature sensor (6).

10. Device (1) according to at least one of the preceding claims, comprising a coupling element for attachment to the container (2), comprising a base body with a contact surface which is designed in such a way that the base body can be placed flat against the container by means of the contact surface, wherein the base body has a bore for receiving at least the temperature sensor (6), and wherein a longitudinal axis of the bore runs tangentially to the contact surface.

11. Method for determining and/or monitoring the temperature (T) by means of a device (1) according to at least one of the preceding claims, comprising the following method steps: detecting a temperature (T) of the medium (M) by means of a first temperature sensor (6), and

Heating or cooling of a predeterminable area (B) of the device (1), in which area at least the first temperature sensor (6) is located, by means of a heating/cooling unit (8).

12. The method according to claim 11, wherein a heating / cooling signal for the heating / cooling element (8) is selected such that a temperature gradient (DT) in the predetermined range (B) is minimized.

13. The method according to claim 10 or 11, wherein the heating / cooling element (8) is regulated or controlled by means of an adjustable heating / cooling signal.

14. The method according to at least one of the preceding claims, wherein the heating/cooling signal is set as a function of a differential temperature value determined by means of the first (6) and second temperature sensor (10) or by means of the differential temperature sensor (14).

15. The method according to claim 14, wherein the heating/cooling signal is adjusted in such a way that the differential temperature value determined by means of the first (6) and second temperature sensor (10) or by means of the differential temperature sensor (14) is minimized.