MEASURING INSERT FOR TEMPERATURE MEASUREMENT

Information

  • Patent Application
  • 20120250725
  • Publication Number
    20120250725
  • Date Filed
    November 09, 2010
    14 years ago
  • Date Published
    October 04, 2012
    12 years ago
Abstract
A temperature measuring insert composed of ceramic or sintered materials of magnesium oxide or aluminum oxide accommodates, on its end facing the measured medium, temperature sensor elements, such as thermocouples and temperature measuring resistors, as a measuring tip, installable singly or with others in metal or ceramic protective tubes. The site of the measuring tip, a water adsorption behavior differing from the remaining measuring insert material is present, in order to protect the temperature sensor elements in the case of rapid process related temperature changes, in order to prevent, in the case of heating, effects due to superheated steam. A solution is provided by features including that the measuring insert has a jacketing comprising densified desiccant coatings, which have a gradient with a continuously or stepwise adapted water adsorptive behavior in the direction of the temperature sensor element, wherein, for example, a decreasing water adsorption is realized according to the invention by means of different fractions of modified and unmodified adsorbents as well as hydrophobic, super hydrophobic or hydrophobized ceramic parts.
Description

The invention relates to a measuring insert serving for temperature measurement and comprising a ceramic, or a magnesium oxide or an aluminum oxide, sintered material, wherein its end facing the measured medium accommodates temperature sensors at a measuring tip. Examples of temperature sensors include thermocouples, and temperature measuring resistors composed of a wire helix or a thin film. Such measuring inserts are known, for example, from Offenlegungsschrift DE 102007036693 A1.


Individual or multiple measuring inserts are inserted in metal or ceramic protective tubes, which, as medium contacting jackets, are exposed to process related, sometimes drastic, temperature changes, wherein moisture adsorptively bound to the ceramic sintered material can be released upon sudden temperature increase, this having disadvantageous effects directly on the temperature sensor element and leading to the formation of condensate, which can result in corrosion phenomena in the protective tube.


According to the state of the art, for the manufacture of temperature measuring inserts, usually prefabricated small tube stock pieces composed of magnesia (MgO) or aluminum oxide, semi-finished parts are equipped with temperature sensors and lead wires and inserted in metal sleeves, wherein a sealing action is usually not achieved and disadvantageous condensation can affect the total inner space including the sensor leads, depending on warehouse conditions and humidity.


The adsorptive behavior of water on molecular sieves such as zeolites or silica gels can be characterized by the curve of the appropriate adsorption isotherm, wherein the amount of the adsorbate on the adsorbent can be presented, for example, as a function of the partial pressure at constant temperature.


The adsorption of water on pore forming phases, such as aluminum oxide, Al2O3, or similarly structured metal oxides, can lead to multilayered buildup, wherein the adsorption isotherms, with increasing steam partial pressure, first experience a flattening of the buildup, before rising greatly again upon the formation of subsequent layers, followed at still higher partial pressures by condensate formation.


A tightly bound H2O monolayer on an Al2O3 surface can have a very high adsorption enthalpy and, as a result, can only be removed by means of high temperature or high temperature vacuum treatments.


The temperature dependence of steam partial pressure, in the case of pressed ceramic parts of the type which can be present in a measuring insert, can be shown by adsorption isosteres; an adsorption isostere for steam shows steam partial pressure at constant volume rising exponentially as a function of temperature.


Ceramic materials, such as aluminum oxide or comparable metal oxides, which, depending on pretreatment, can be open pored and have open pored adsorption locations, only require moderate desorption enthalpies for weakly adsorbed water molecules in order to transfer the water back into the gaseous phase, wherein, in the case of the presence of supplementally present condensates, only the evaporation enthalpy is to be applied.


Thus, in the case of usual process related heating, a marked steam partial pressure can occur in the immediate vicinity of ceramic materials containing adsorbed moisture.


Moisture present can significantly influence the correct functioning of sensor elements; respectively, subsequent condensate formation following cooling can, for example, contribute to irreversible corrosion effects on temperature sensors or their leads.


An object of the present invention, consequently, is to provide a measuring insert, which overcomes the described disadvantages of the state of the art.


According to the invention, the object is achieved by features including that the measuring insert has functionalized surface areas adjoining one another, wherein the adsorptive behaviors of a liquid on these surface areas differ from one another. In this way, the disadvantageous influence of moisture, as steam or condensate, on the thermometer, for example, after rapid process related temperature changes can be avoided. In given cases, moisture forming on the surface of the measuring insert can be diverted by the application of functionalized surfaces, which differ in regard to their adsorptive behaviors.


In an embodiment of the measuring insert, the functionalized surface areas serve to conduct a liquid from a surface area of the measuring insert toward a surface area having a higher affinity as regards the adsorption of the liquid. For such purpose, for example, specific materials or a specific sequence of functionalized surface areas, i.e. a specific arrangement, can be applied.


In an additional embodiment, the measuring insert has a measuring tip, which is in thermal contact with a measured material during a measurement operation.


In an additional embodiment, the measuring tip has a functionalized surface area, which, in comparison with at least one other surface area of the measuring insert, has the smallest affinity as regards adsorption of the liquid. In this way, it can be assured that, in the area of the measuring tip, no damage is done due to a deposition of moisture.


In an additional embodiment, the affinity for adsorption of the liquid on the surface of the measuring insert increases with increasing distance from the measuring tip. In this arrangement it is advantageous, that, through the proposed distribution of the adsorptive behavior, depositing moisture, i.e. liquid, is led, for example, as far as possible away from the measuring tip.


In an additional embodiment, the change of the adsorptive behavior between the functionalized surface areas is stepwise. The functionalized surface areas can thus be so arranged that the adsorptive behavior changes abruptly at a transition between surface areas.


In an additional embodiment, the adsorptive behavior between the functionalized surface areas changes continuously. I.e., the adsorptive behavior can continuously change as a function of the position on the surface of the measuring tip, for example, with increasing distance from the measuring tip.


In an additional embodiment of the measuring insert, in the area of the measuring tip, there is a temperature sensor, which serves for registering the temperature of a measured material and which is at least partially embedded in the measuring insert.


In an additional embodiment, the temperature sensor is connected to the conductors of a sheathed cable, wherein the measuring tip, respectively the temperature sensor at least partially embedded therein, seals the sheathed cable on an end, and the surface of the sheathed cable in the region of the measuring tip and the functionalized surface areas of the adjoining surface of the sheathed cable differ from one another by having different adsorptive behaviors. In such case, it can be sufficient that only a part of the total surface of the measuring insert has, functionalized surface areas.


In an additional embodiment of the measuring insert, the functionalized surface areas having different adsorptive behavior comprise different parts, especially modified or unmodified water adsorbers and/or a hydrophobic, super hydrophobic or hydrophobized ceramic.


In an additional embodiment, the surface of the measuring insert has a coating having a uniform coating thickness, especially with a coating thickness of 0.2 to 5 mm, wherein the coating, in the direction toward the temperature sensor, has a gradient with decreasing water adsorption. The measuring insert can have, for example, a jacketing comprising densified, compressed, desiccant coatings, which, toward the temperature sensor element, have a gradient having continuously or stepwise adapted, water adsorptive behavior, wherein, for example, a decreasing water adsorption is realized by means of different fractions of modified and unmodified adsorbents as well as hydrophobic, super hydrophobic or hydrophobized ceramic parts. The functionalized surface areas can be formed by this jacketing, for example.


In an additional embodiment, the adsorptive behavior of the functionalized surfaces is influenced by means of water adsorbers, wherein the water adsorbers have different adsorption capacities, or different adsorption isotherms.


In an additional embodiment, the adsorptive behavior of the functionalized surface areas is influenced by means of a hydrophobic, super hydrophobic and/or hydrophobized ceramic.


In an additional embodiment, the coating comprises water adsorbers having a uniform adsorption capacity as well as a uniform adsorption isotherm and has a coating thickness, which becomes thinner toward the measuring tip, in which the sensor element is embedded.


The measuring insert can have, for example, a jacketing comprising densified desiccant coatings, which, toward the temperature sensor, which is arranged in the area of the measuring tip, have a gradient with a continuously or stepwise adapted water adsorptive behavior, wherein different fractions of modified and unmodified adsorbents as well as hydrophobic, super hydrophobic or hydrophobized ceramic parts can be applied, in order to reduce the water adsorbtion affinity.


According to an embodiment of the invention, in the immediate vicinity of the temperature sensor and the connection lines, coatings having uniform coating thicknesses of 0.2 to 5 mm are applied, wherein the adsorbents applied therefor have a gradient. The layer segment directly surrounding the temperature sensor element, consequently, does not tend to enable multilayer adsorption and does not have a high adsorption capacity and borders, depending on the arrangement, in each case, on coating zones, which accommodate excess steam from the sensor zone by means of diffusion processes in the direction of the coating having higher moisture affinity.


An embodiment provides that the coating has a stepped gradient. Another embodiment provides that the coating has a continuous gradient.


In an additional embodiment, the measuring insert has a coating, which has a gradient formed by means of water adsorbents, which have different adsorption capacities, or different adsorption isotherms.


Another embodiment provides that, as water adsorber, partially modified and unmodified 4 Angstrom to 8 Angstrom molecular sieve material in a mixing ratio from 80:1 to 2:1 is applied as jacket material.


Another embodiment provides that, as water adsorber, zeolites having different adsorption capacities, or different adsorption isotherms, are applied in different mixing ratios as jacket material.


An additional embodiment provides that, as water adsorbing desiccant, compressed magnesium oxides and unmodified 4 Angstrom to 8 Angstrom molecular sieve material in a mixing ratio from 70:1 to 3:1 are applied as jacket material.


In an additional embodiment, the coating zone, which borders the sensor element in its immediate vicinity and surrounds such, has, in addition to the adsorbents having the lowest adsorption capacity, supplements of hydrophobic, super hydrophobic and hydrophobized ceramic parts, wherein the water collecting affinity is markedly reduced.


In an additional embodiment, the measuring insert has a coating, which comprises water adsorbers having a uniform adsorption capacity as well as a uniform adsorption isotherm, and a coating thickness, which becomes thinner toward the sensor element.


In an additional embodiment, the jacketing comprises water adsorbers, which have a coating thickness that becomes thinner in the direction toward the sensor element, wherein the coating supplementally has a gradient with decreasing water adsorption in the direction toward the sensor element.


An embodiment provides that the coating, whose coating thickness becomes thinner in the direction toward the sensor element, supplementally has a stepped gradient.


An embodiment provides that the coating, whose coating thickness becomes thinner in the direction toward the sensor element, supplementally has a continuous gradient.


In an additional embodiment, the jacketing of the measuring insert has a rectangularly prismatic, polygonally prismatic, cylindrical or conical form.





The invention will now be explained in greater detail based on the appended drawings, the figures of which show as follows:



FIG. 1 a compact thermometer for application in a process;



FIG. 2 a schematic representation of a section through the longitudinal axis of an embodiment of a measuring insert having a stepped change of adsorptive behavior in FIG. 2a) and a continuous change in FIG. 2b);



FIG. 3 a schematic representation of a section through the longitudinal axis of an additional embodiment of a measuring insert having a stepped change of adsorptive behavior in FIG. 3a) and a continuous change in FIG. 3b);



FIG. 4 a schematic representation of a protective jacket equipped with a measuring insert; and



FIG. 5 a schematic representation of a section through a protective tube equipped with two measuring inserts.






FIG. 1 shows a so called compact thermometer 22 comprising: a metal protective tube 18, for example, of a steel alloy such as 316 L or Inconel; and a measuring insert 1 fitted within the protective tube. A so called head transmitter 21, i.e. a measurement transmitter, which serves for processing the measuring signals recorded by means of the measuring insert, is connected to measuring insert 1.



FIG. 2 shows schematic representations of sections through different embodiments of measuring insert 1. FIG. 2a) shows a measuring insert 1 having coatings 11 of approximately uniform coating thickness, for example, a coating thickness from 0.2 to 5 mm, which has a stepped gradient 5 exhibiting a decreasing water adsorption capacity. FIG. 2b) shows measuring insert 1, which likewise has an approximately uniform coating thickness coupled, in this case, with a continuous gradient 6 exhibiting a decreasing water adsorption capacity.



FIG. 3
a) shows a cross section of measuring insert 1 having a coating thickness, which becomes thinner in the direction toward the temperature sensor located at the tip of the measuring insert 1, wherein coating 11 supplementally has a stepped gradient 7 exhibiting a decreasing water adsorption in the direction toward the temperature sensor. FIG. 3b) shows measuring insert 1 having a coating thickness, which becomes thinner, wherein the coating supplementally has a continuous gradient 8 exhibiting a decreasing water adsorption capacity.



FIG. 4 shows in cross section the lower segment of a protective tube 18 containing a measuring insert 1. During measurement operation, this segment contacts the measured material. Protective tube 18 comprises a metal alloy. Temperature sensor 9 of the measuring insert 1 is in thermal contact with the end of the protective tube. Furthermore, FIG. 4 shows how temperature sensor 9, which is contacted with the electrical leads 10, is surrounded by a part of coating 11, which has, for example, the lowest adsorption capacity. Coating 11 has a stepped water adsorption gradient. In an additional embodiment of the invention, the part of coating 11 surrounding temperature sensor 9 is surrounded by hydrophobic, super hydrophobic or hydrophobized ceramic parts, in order to further reduce the water collecting affinity.



FIG. 5 shows a cross section of a ceramic protective tube 17 equipped with two measuring inserts 1, 3, wherein the measuring inserts 1, 3, have coatings 11 with coating thicknesses that become thinner and supplementally a stepped gradient 7 with a decreasing water adsorption in the direction toward the temperature sensor. The jacketed lower coating segment of coatings 11 in immediate contact with temperature sensor 9 has, for example, a low water adsorption capacity and, in an additional embodiment, has hydrophobic, super hydrophobic or hydrophobized ceramic parts, with which the water collecting affinity is reduced directly at the temperature sensor 9.


LIST OF REFERENCE CHARACTERS




  • 1 measuring insert


  • 5 stepped gradient, decreasing water adsorption with constant coating thickness


  • 6 continuous gradient, decreasing water adsorption with constant coating thickness


  • 7 stepped gradient, decreasing water adsorption with decreasing coating thickness


  • 8 continuous gradient, decreasing water adsorption with decreasing coating thickness


  • 9 temperature sensor


  • 10 connection leads


  • 11 coating


  • 18 protective tube


  • 19 measuring tip


  • 21 head transmitter


  • 22 compact thermometer


Claims
  • 1-14. (canceled)
  • 15. The measuring insert for a thermometer having a protective jacket, the measuring insert has functionalized surface areas adjoining one another, wherein: adsorptive behaviors of a liquid on said functionalized surface areas differ from one another.
  • 16. The measuring insert as claimed in claim 15, wherein: said functionalized surface areas serve to conduct a liquid from a surface area of the measuring insert toward a surface area having a higher affinity as regards the adsorption of the liquid.
  • 17. The measuring insert as claimed in claim 15, wherein: the measuring insert has a measuring tip, which is in thermal contact with a measured material during measurement operation.
  • 18. The measuring insert as claimed in claim 17, wherein: said measuring tip has a functionalized surface area, which, in comparison with at least one other surface area of the measuring insert, has the lowest affinity as regards the adsorption of liquid.
  • 19. The measuring insert as claimed in claim 17, wherein: the affinity for adsorption of liquid on the surface of the measuring insert increases with increasing distance from said measuring tip.
  • 20. The measuring insert as claimed in claim 15, the change of the adsorptive behavior between the functionalized surface areas is stepwise.
  • 21. The measuring insert as claimed in claim 15, wherein: the change of the adsorptive behavior between said functionalized surface areas is continuous.
  • 22. The measuring insert as claimed in claim 15, wherein: a temperature sensor, which serves for registering the temperature of a measured material, is at least partially embedded in the measuring insert in the area of said measuring tip.
  • 23. The measuring insert as claimed in claim 15, wherein: a temperature sensor is connected to the conductors of a sheathed cable;said measuring tip, or the temperature sensor at least partially embedded therein, seals the sheathed cable at one end; andthe surface of the sheathed cable in the area of said measuring tip and said functionalized surface areas of the adjoining surface of the sheathed cable have adsorptive behaviors, which differ from one another.
  • 24. The measuring insert as claimed in claim 15, wherein: said functionalized surface areas having different adsorptive behaviors comprise different parts, especially modified or unmodified water adsorbers and/or a hydrophobic, super hydrophobic or hydrophobized ceramic.
  • 25. The measuring insert as claimed in claim 15, wherein: the surface of the measuring insert has a coating with a uniform coating thickness, especially a coating thickness of 0.2 to 5 mm; andthe coating has a gradient with decreasing water adsorption in the direction toward the temperature sensor.
  • 26. The measuring insert as claimed in claim 15, wherein: the adsorptive behavior of the functionalized surfaces is influenced by means of water adsorbers; andthe water adsorbers have different adsorption capacities or different adsorption isotherms.
  • 27. The measuring insert as claimed in claim 15, wherein: the adsorptive behavior of said functionalized surfaces is influenced by a hydrophobic, super hydrophobic and/or hydrophobized ceramic.
  • 28. The measuring insert as claimed in claim 15, wherein said coating comprises water adsorbers having a uniform adsorption capacity as well as a uniform adsorption isotherm and has a coating thickness, which becomes thinner toward the temperature sensor.
Priority Claims (1)
Number Date Country Kind
102009054747.9 Dec 2009 DE national
PCT Information
Filing Document Filing Date Country Kind 371c Date
PCT/EP2010/067148 11/9/2010 WO 00 6/14/2012