RU105441U1 - THERMOELECTRIC CONVERTER FOR HIGH TEMPERATURE AND AGGRESSIVE MEDIA - Google Patents

Abstract

1. Thermoelectric converter for high-temperature and aggressive media, including platinum-containing thermoelectrodes, isolated from each other by ceramic straws and placed in protective fittings, consisting of outer and inner ceramic covers, and a platinum tip mounted on the outer surface of the inner ceramic cover, fixed by the lower end of the outer ceramic case, characterized in that one or more flats are made on the outer surface of the inner ceramic case in the area of fastening of the platinum tip, and the platinum tip is crimped over the surface of the inner ceramic case and pressed into the flats. ! 2. Thermoelectric transducer for high-temperature and aggressive media according to claim 1, characterized in that the flats are made with an ellipsoidal or truncated pyramidal surface. ! 3. Thermoelectric transducer for high-temperature and aggressive media according to claim 1, characterized in that the flats are made with the major axis of the resulting ellipsoidal surface or cone-ellipsoidal surface along the generatrix of the surface of the inner ceramic cover or at an angle to it and their depth does not exceed 1 /3 wall thickness of the inner ceramic cover. ! 4. A thermoelectric transducer for high-temperature and aggressive media according to claim 2, characterized in that the flats on the surface of the inner ceramic case are made with the major axis of the ellipsoidal surface or the truncated pyramidal surface located along the generatrix of the outer surface of the inner ceramic case or under

Description

The thermoelectric transducer for high-temperature and aggressive environments, claimed as an invention, relates to measuring technique and is intended to measure the temperature of the molten glass, where the temperature can reach 1500 ° C.

When measuring the temperature of glass melts, thermocouples with ceramic covers and platinum tips are recommended for use in chemically aggressive and high-temperature environments. The use of a platinum tip as a protective cover avoids the destruction of the outer cover due to the chemical and abrasive effects of the melt (especially in glass sampling devices), increases the measurement speed and tracks sharp temperature fluctuations, thereby improving product quality.

Known thermoconverter, including interconnected and mounted in the shell functional units - a thermosensitive unit with mineral insulation, a working junction and a site for terminating lead conductors, while the thermocouple is equipped with a protective cover placed on the shell, which, according to one of the options, is made of refractory non-ferrous metals and in contact with its inner surface with the outer surface of the shell of the heat-sensitive node, and the length of the protective cover is made equal to or greater than ling working zone thermocouple. (one).

A disadvantage of the known thermal converter is the complexity of the technology of filling mineral insulation in the form of a powder in the manufacture of thermal converters with a cross-sectional diameter of the protective cover up to 9-10 mm., And the deterioration of the quality of thermal converters during operation, because during the formation of voids in the filling during their operation, diffusion of additional ingredients from platinum-containing thermoelectrodes is possible, as well as the high cost of thermal converters due to the expensive alloy used for a protective cover of large lengths and diameters.

A reference thermoelectric converter is also known, consisting of thermoelectrodes isolated from each other, connected at one end, made of platinum-containing materials and placed in a cover, while the thermoelectrodes are isolated from each other and from the cover by a powder of mineral insulation, and the cover is made of heat-resistant alloy , for example, from an alloy containing platinum and rhodium. (2)

A disadvantage of the known device is also the complexity of the technology of filling mineral insulation in the form of powder in the manufacture of thermal converters of large length with a cross-sectional diameter of the protective cover up to 9-10 mm. In addition, the use of an expensive alloy containing platinum and rhodium for the manufacture of a protective cover causes the high cost of thermal converters.

The closest technical solution to the purpose, technical nature and the achieved result is a thermoelectric transducer designed to measure the temperature of glass melts, including an external safety metal tube connected to the head for placement of contact terminals, platinum-containing thermoelectrodes isolated from each other by ceramic straws with channels and placed into protective fittings consisting of internal and external ceramic covers, while the end of the outer the surface of the inner ceramic cover is reinforced with a platinum tip fixed to the lower end of the outer ceramic cover. (3)

The disadvantage of this thermal converter is a decrease in the reliability of the design during operation, because during periodic measurements of temperature, due to the difference in the coefficients of thermal expansion of metal and ceramics, it is possible to weaken the fastening and shift the reinforcing platinum tip and damage the surface of the ceramic cover. To increase the reliability of fastening the platinum tip, it is necessary to increase its wall thickness and length by introducing the tip into the outer ceramic case, which leads to an increase in the cost of the thermoelectric converter.

The technical effect of the thermoelectric converter claimed as an invention for high-temperature and aggressive environments is to increase the reliability of the thermoelectric converter when used, and to reduce its cost in manufacturing.

The technical result when using the proposed technical solution is to increase the reliability of fixing the protective platinum cover on the surface of the inner ceramic cover and the possibility of reducing the wall thickness of the protective platinum cover.

To achieve the specified technical result in a thermoelectric converter for high-temperature and aggressive environments, including platinum-containing thermoelectrodes, isolated from each other by ceramic straws and placed in protective fittings consisting of external and internal ceramic covers, and a platinum tip mounted on the outer surface of the internal ceramic cover, fixed the lower end of the outer ceramic case according to the invention, on the outer surface of the inner one or more flats with an ellipsoid or pyramidal truncated surface is made in the ceramic cover in the area of the platinum tip attachment, and the platinum tip is pressed over the surface of the internal ceramic cover and pressed into the flats, while the flats on the surface of the internal ceramic cover are made with the axis of the ellipsoid surface or the pyramidal a truncated surface along the generatrix of the surface of the inner ceramic cover or at an angle to it and with their displacement around the circumference and along the longitudinal axis of the inner ceramic cover and placed in a spiral line, in addition, the depth of the flats on the surface of the internal ceramic cover does not exceed 1/3 of the wall thickness of the ceramic cover.

In the claimed technical solution, the execution of the flats on the outer surface of the inner ceramic cover of the thermal converter allows to increase the reliability of fixing the platinum tip, crimped over the surface of the ceramic cover and pressed into the flats, and makes it possible to significantly reduce the thickness of the platinum tip.

These signs are necessary and sufficient to achieve a technical result and determine the inventive step of the claimed technical solution.

Performing flats with the location of the major axis of the formed ellipsoid surface or a pyramidal truncated surface along the generatrix of the surface surface of the inner ceramic cover or at an angle to it, with a displacement along the circumference and along the longitudinal axis of the ceramic cover leading to their location along a spiral line, allows you to vary the amount of crimping force platinum tip and the thickness of its walls. Under certain production conditions that determine the type of thermoelectric converter and the wall thickness of the platinum tip, the optimal shape of the flats is selected, their location, depth and quantity on the surface of the inner ceramic cover. Performing flats with an ellipsoidal surface will require less crimping force and can be used with a larger thickness of the platinum tip, and performing flats with a pyramidal truncated surface will increase the reliability of fastening the platinum tip and makes it possible to reduce its wall thickness. Limiting the depth of flats 1/3 of the wall thickness of the inner ceramic cover will allow you to maintain sufficient strength of the latter. The proposed surface shape is flatter when executed along an ellipsoid or pyramidal truncated surface and the placement on the surface of the inner ceramic cover with an offset that determines their location along a spiral line, clarifies the possible options for performing flats.

An example of the implementation of the proposed technical solution is illustrated by drawings.

In figure 1. a longitudinal section of a thermoelectric converter with two thermocouples is presented;

Fig. 2 shows a cross section AA in Fig. 1;

Figure 3 presents the leader B with figure 2: options for performing flats with an ellipsoidal surface and a pyramidal truncated surface.

Figure 4 shows the implementation of the flats with an ellipsoidal surface with the location of the larger axis parallel to the central axis of the inner ceramic cover.

Figure 5 shows the execution of flats with a pyramidal truncated surface with the location of the larger axis at an angle to the central axis of the inner ceramic cover.

The thermoelectric transducer for high-temperature and aggressive environments contains two thermocouples, consisting of platinum rhodium 1 and platinum 2 thermoelectrodes, isolated from each other by four-channel ceramic straws 3 and enclosed in an internal ceramic cover 4 and outer ceramic cover 5, designed to protect thermocouples from the aggressive effects of high-temperature environments . The end of the inner ceramic cover 4 protruding from the outer ceramic cover 5 on the outer surface is reinforced to protect the thermocouples from the chemical and abrasive effects of the medium by a platinum tip 6, fixed by the lower end of the outer ceramic cover and a layer 7 of heat-resistant binder. On the outer surface of the outer end of the ceramic cover 4 there are flats 8 with an ellipsoid surface or 9 with a pyramidal truncated surface. The flats are made with the location of the major axis of the ellipsoid or pyramidal truncated surface parallel to the central axis 10 of the cylindrical surface of the ceramic cover or at an angle to it and placed with offset around the circumference and along the longitudinal axis of the latter, which determines their location along the spiral line 11. On the outer ceramic cover 5 put on and fixed by a layer of heat-resistant binder and screw 12, a safety metal tube 13, which serves to connect the outer ceramic cover 5 with the head 14, is designed ennoy to accommodate the relay terminals 15, which serve for the connection with commutation thermoelectrodes thermocouple wires measuring electronic circuit device (not shown).

When assembling a thermoelectric converter on the outer surface of the inner ceramic cover, flats 8 or 9 are performed to a depth of no more than 1/3 of the wall thickness of the ceramic cover, placing their major axes parallel to the central axis 10 of the internal ceramic cover or at an angle to the latter and along the spiral line 11. Protective the platinum tip 6 is crimped on the surface of the inner ceramic cover 4 and on the surface of the flats 8 or 9, after which the inner ceramic cover, with thermocouples placed in it, is fixed with the heat resistant binder 7 in the outer ceramic case 5, the lower end of which is also fixed platinum tip. Then, thermocouples 1 and 2 are placed in the ceramic ceramic 4 in the inner ceramic case 4, and the internal ceramic case is placed inside the external ceramic case 5. After installation on the surface of the external ceramic case 5 and fixing it with a layer of heat-resistant binder and screw 12 of the metal safety tube 13, which serves for the connection of the outer ceramic cover 5 with the head 14, the conclusions of the thermoelectrodes 1 and 2 are fixed to the contact terminals 15, which serve to connect the thermocouples of the thermocouples to the switching the wires of the measuring circuit of the electronic device (not shown in the drawing).

When measuring the temperature of the molten glass, the outer end of the inner ceramic cover 4 reinforced with a platinum tip 6 is gradually lowered into the molten glass. The magnitude of the thermoelectromotive force arising between the free ends of platinum 2 and platinum rhodium 1 thermoelectrodes in the head 14, is converted into convenient for reading or recording readings of an electronic measuring device connected by switching wires (not shown) to the terminals of terminal 15 in the head 14

According to the testimony of an electronic measuring device, the temperature of the molten glass is determined.

Due to the reliability of fixing the platinum tip, the possibility of mechanical damage to the internal ceramic cover with the thermocouple sleeves located in it is eliminated, the reliability of the thermocouple is increased and the possibility of reducing the wall thickness and length of the platinum tip is provided, To protect the surface of the protruding end of the inner ceramic cover, it becomes sufficient to use a platinum tip with a foil thickness and a length corresponding to the immersion depth of the thermal converter in the working medium.

Sources of information taken into account:

1. Description of the utility model of the Russian Federation No. 23344 by class. G01R 19/03, published 06/10/2002.

2. Description of the utility model of the Russian Federation No. 39704, IPC: G01K 15/00, published. 04/10/2004

3. Description of the patent for a utility model of the Russian Federation No. 57515 by class. H01L 35/00, published October 10, 2006 (Prototype)

Claims (5)

1. Thermoelectric converter for high-temperature and aggressive environments, including platinum-containing thermoelectrodes, isolated from each other by ceramic straws and placed in protective fittings consisting of external and internal ceramic covers, and a platinum tip mounted on the outer surface of the internal ceramic cover, fixed by the lower end of the external ceramic case, characterized in that on the outer surface of the inner ceramic cover in the area of attachment of platinum n konechnika executed by one or more flats, and the platinum tip is crimped on the internal surface of the ceramic cover and is pressed into the flats. 2. Thermoelectric converter for high-temperature and aggressive environments according to claim 1, characterized in that the flats are made with an ellipsoid or truncated pyramidal surface. 3. Thermoelectric transducer for high-temperature and aggressive environments according to claim 1, characterized in that the flats are made with the location of the larger axis of the formed ellipsoid surface or cone-ellipsoid surface along the generatrix line of the surface of the inner ceramic cover or at an angle to it and their depth does not exceed 1 / 3 wall thickness of the inner ceramic cover. 4. Thermoelectric transducer for high-temperature and aggressive environments according to claim 2, characterized in that the flats on the surface of the inner ceramic cover are arranged with the major axis of the ellipsoid surface or a truncated pyramidal surface along the generatrix of the outer surface of the inner ceramic cover or at an angle to the generatrix. 5. The thermoelectric converter for high-temperature and aggressive environments according to claim 1, characterized in that the flats on the surface of the inner ceramic cover are offset along the circumference and along the longitudinal axis of the internal ceramic cover and are arranged in a spiral line.