RU2780306C1 - High temperature thermocouple calibration system - Google Patents

Abstract

FIELD: calibration equipment.

SUBSTANCE: proposed installation refers to the means and equipment that provides calibration and graduation of thermoelectric converters in the temperature range above 2000 K. The high-temperature installation for calibrating thermocouples contains a housing made of refractory material, a heater with current leads placed inside the housing, heat-resistant electrical insulators in a protective tube. The body is made of heat-insulating material in the form of a parallelepiped with a through inner cylindrical hole and two end caps. The heater of the installation is made of four radiators, which are connected in series with each other. The heater is installed inside the housing opening, and the heater current leads coming from the radiators are placed in the grooves of the end caps and removed from the installation housing far from the heating zone. Along the axis of the hole on heat-resistant screens built into the end caps, a high-temperature protective tube is fixed with annular heat-resistant disks evenly spaced inside - electrical insulators for fastening thermocouples. The high-temperature pipe is made with a ratio of its length to diameter equal to 25.

EFFECT: providing a simplification of the thermocouple calibration procedure while improving the accuracy of measurements with a calibrated thermocouple.

4 cl, 3 dwg

Description

The proposed high-temperature installation for calibrating thermocouples belongs to the facilities and equipment that provide research in the field of heat transfer. In many problems of heat engineering, the problem of measuring high temperatures (more than 2000 K) arises.

For example, in many problems of thermal physics, especially for studying the characteristics of new heat-resistant materials, including composite materials, operating under difficult temperature conditions, accurate temperature measurement is required. Measuring temperatures above 2000 K presents significant difficulties, both in terms of the availability of such materials for the electrodes of temperature sensors (thermocouples), and their calibration or calibration due to the lack of appropriate equipment and methods for its implementation.

Measurement of temperatures above 2000 K can be carried out with a limited number of existing thermocouples, which include VR5/20 thermocouples with A ₁ graduation up to a temperature of 2773 K, VR5/26 thermocouples with C graduations up to a temperature of 2573 K, and iridium-palladium thermocouples up to a temperature of 2500 K.

However, in the temperature range above 2000 K, there is practically no equipment and methodology for reliable metrological control and reliable calibration, which hinders the industrial use of these thermocouples. According to LLC Obninsk Thermoelectric Company, until now “their widespread use at temperatures above 1700°C is limited, including due to the lack of reliable metrological control and reliable calibration both at the manufacturing stage and during operation.”

A known method for calibrating VR thermocouples in a horizontal furnace with a graphite heater in the cavity of a graphite emitter installed inside the heater (Ulanovsky A., Fisher J., Oleinikov P., Zaitsev P., Pokhodun A. Features of high-temperature calibration of tungsten-rhenium thermomares // International Journal of Thermophysics, 2015, No. 36, (2-3), pp. 433-443).

This method has the following disadvantages.

1. The thermocouple being calibrated is not shielded from graphite vapor, which causes distortion of the calibration curve due to shunting of the thermocouple signal.

2. Exposure of the thermocouple forces the calibration to be carried out in the shortest possible time with shock heating and cooling of the thermocouple, which also causes distortion of the calibration curve.

3. The horizontal location of the thermocouple in the furnace causes the thermocouples to bend at high temperatures and increases the risk of an accidental short circuit to the heater or furnace elements.

Known protective tube (patent CN102944332 A, IPC G01K 15/00, 03.12.2012), which provides protection for tungsten-rhenium thermocouples during high-temperature calibration in the temperature range of 1500 - 2300°C. The calibration process takes place inside a protective tube made of tungsten, which has a separate chamber at its working end, structurally close to a black body. A tungsten-rhenium thermocouple is inserted from the upper end of the tube with a mounting flange and passed through the upper and lower screens, made up of tungsten plates with holes for the passage of thermocouples. The thermocouple is inserted so that its working junction is in the uniform temperature zone of the protective tube. The upper flange is sealed to protect the internal atmosphere of the furnace from air penetration, including inside the protective tube. Before heating the furnace, the protective tube is evacuated and filled with an inert gas. Tungsten is used as the material of the protective tube, graphite or tungsten tube can serve as the heating element of the furnace. The main disadvantages of this analogue are as follows:

1. A small zone of uniform heating and a short time spent by the thermocouple in the working zone leads to uneven heating and an increase in the calibration error,

2. Difficulty of inserting a thermocouple into the working area at high temperature levels (above 2000 K),

3. Possibility of shorting the thermocouple to the heater or parts of the furnace when the thermocouple thermoelectrodes are bent,

4. Difficulty in sealing the working end of the protective tube against air penetration at very high temperatures (above 2000°C).

As a prototype, in terms of the capabilities and quality of calibration and calibration, a device for calibrating high-temperature thermocouples (patent No. 2 720 819 IPC G01K 15/00, 05/13/2020) was chosen, consisting of a protective cover (case) made of refractory material with a mounting flange, thermocouples with ceramic insulators, block emitter. It is located vertically, the protective cover is hermetically sealed from the working end with a plug, inside the protective cover the carrier tube is coaxially installed with working thermocouple junctions fixed on it, the carrier tube is hermetically plugged from the working end with a reflective plug. The protective cover and carrier tube have holes for filling with inert gas. A protective cover with a carrier tube and thermocouple thermoelements fixed on it is placed in the working cavity of the emitter unit, and the emitter unit is fixed on the composite electric heater. On the side of the emitter block, opposite to its working cavity, there is a hole for sighting the pyrometer.

The disadvantages of the prototype, in our opinion, include the following:

1. The uniform heating area in the thermocouple area 2 is small, and uneven heating may occur,

2. Indirect control over the temperature of calibrated thermocouples using a reflector plug 5 can lead to errors due to the fastening points of the thermocouples and the reflector plug that are remotely separated from each other,

3. The complex design of the device, especially in the area of the working cavity of the device, the difficulty of maintaining the alignment of all structural elements: the emitter unit 11, the protective cover 6, the carrier tube 4 and the composite electric heater.

The objective and technical result of the present invention is to create an installation for calibrating thermocouples, which makes it possible to calibrate thermoelectric converters in the temperature range of 2000-2500 K with the exception of temperature measurement errors associated with mounting thermocouples.

The solution of the problem and the technical result are achieved by the fact that in a high-temperature installation for calibrating thermocouples, containing a housing made of a refractory material, a heater with current leads, an exemplary thermocouple, that the housing is made in the form of a parallelepiped with a through inner cylindrical hole and two end caps, the installation heater is made Of the four emitters fixed on the current leads located in the covers, the emitters are connected in series with each other and form a square, the heater is installed inside the housing opening, the heater current leads coming from the emitters are laid in the grooves of the end caps and removed from the installation housing far from the heating zone, along the axis of the hole on heat-resistant screens built into the end caps, a high-temperature pipe is fixed with annular heat-resistant electrical insulators evenly spaced inside, designed to install reference and calibrated thermocouples, the high-temperature pipe is made with a length to diameter ratio of 25.

The emitters are made of UKKM material (or), for example "Uglekon-T". Insulator disks for fastening thermocouples are made 5-10 mm thick and installed with a step of 50 mm.

The essence of the present proposal can be explained with the help of the following drawings presented in the figures:

The figure 1 shows a general view of the proposed installation.

The figure 2 shows a section of the installation.

The figure 3 shows the scheme of testing.

The installation (see Fig. 1) contains a housing 1 made of a heat-resistant material (for example, ShVP-1800K or Ultra Board-2023 K) in the form of a parallelepiped with a cylindrical through hole inside 2. Inside the hole 2, four emitters 3 are installed and fixed in the form of a square made of composite material UKKM or "Uglecon-T", a heat-resistant pipe 4 with an inner diameter of 010 mm made of high-temperature material (boron nitride, beryllium oxide, hafnium oxide) 250 mm long is mounted along the axis inside the hole. Emitters 3 are connected in series with each other, and their ends and copper current leads 12 are removed from the heating zone. High-temperature thermal insulation 5 made of UKMT material is laid along the periphery of the hole, which ensures retention of the heat flux created by emitters heated to temperatures above 2000 K. Heat-resistant pipe 4 is fixed on end caps 6 made of heat-resistant material Ultra Board-2023 K and screens 7 made of boron nitride NB. The pipe passes through the screens 7, and inside the pipe there are insulating disks 8 5-10 mm thick, made of insulating heat-resistant material (for example, boron nitride) with holes for thermocouples, with a step of 50 mm. At the ends, the heat-resistant pipe is closed with plugs 11 with holes for thermocouples and for observation by a pyrometer 15. In the central part of the heat-resistant pipe 4, on the one hand, there is an exemplary thermocouple 9 calibrated with an accuracy of one degree Kelvin, on the other hand, a calibrated thermocouple 10, structurally similar to the exemplary thermocouple and installed in close proximity to it. The setup is placed in vacuum chamber 14, into which argon is supplied, allowing calibration both in vacuum and in argon at any pressure. Copper current leads 12 from the radiators are brought out of the installation through channels 13 in covers 6 away from the heating zone (Fig. 2). To calibrate the reference thermocouple, a reference pyrometer 15 installed outside the vacuum chamber coaxially with the heat-resistant tube (Fig. 3) can be used.

A feature of this installation is the combination of a heating furnace and a measuring part of thermocouple calibration in one design, which ensures repeatability of tests under the same conditions, maximum thermal insulation and the absence of heat losses along the length of a heat-resistant pipe, and minimal heat energy consumption.

The proposed installation in the calibration mode works as follows:

After mounting the unit 1 in the vacuum chamber 14 and connecting the emitters 3 through copper current leads 12 to the power supply 16, the heat-resistant pipe 4 of the unit is centered at one end coaxially with the pyrometer 15. At the other end, a prepared exemplary thermocouple 9 is installed on insulator disks 8 and inserted to the middle thermocouple 9 is not shielded along the length of heat-resistant pipe 4, since it is laid through insulator disks 8. This reduces the EMF error of the thermocouple to a minimum due to uneven heating of thermoelectrodes along the length. The free ends of the thermocouples are removed from the heating zone and connected through copper conductors to the recorder 17 and the heating automatic control system (ACS) 18 (Fig. 3). The contact points are immersed in a Dewar vessel 19 with melting ice to maintain a temperature of 0°C. The readings of thermocouple 9 are recorded on the recorder 17 or (and) entered into the ACS system by heating 18. The vacuum chamber is evacuated, if necessary, argon is injected from the cylinder 20 and calibrated as follows: heating is started using the ACS heating 18, applying voltage to the emitters 3 through step-down transformer 21 from the thyristor regulator 22 to the first calibration point, after reaching which an exposure is made until the steady state heating mode is reached, after which the readings are simultaneously recorded on the registrar 17 and the exemplary pyrometer 15. Since the heating of the heat-resistant pipe is uniform and the ratio of its length to diameter is 25 , then we can consider the radiating cavity of pipe 4 as approaching the parameters of a “black” body, and all thermocouples placed in this cavity have the same temperature. The temperature measured by the exemplary pyrometer 15 is the true value of the temperature of the working junction of the thermocouple and it corresponds to the recorded reading of the thermo-EMF on the recorder 17.

This process is repeated for other temperatures, then the data is brought into line, and thus the calibration is carried out over the entire temperature range. The calibration of thermoelectric converters (thermocouples) in the temperature range of 2000-2500 K is carried out as follows:

A calibrated thermocouple 10 is installed on the other side of the pipe, structurally similar to the reference thermocouple 9, so that its junction (kinglet) located in close proximity to the reference thermocouple junction. The readings of the latter are recorded on the registrar 17 together with the readings of the thermocouple 9. The readings of both thermocouples are recorded synchronously, so that the characteristic of the calibrated thermocouple is immediately obtained. Tests are carried out according to the same scheme as when calibrating a reference thermocouple.

The salient features of the proposed device are:

The simplicity of the installation design, the absence of temperature measurement errors associated with the fastening of thermocouples and heat exchange inside the central part of the heat-resistant pipe.

A simplified method and technology for mounting and dismounting a calibrated thermocouple, the presence of a heat-resistant electrically insulated housing with a cylindrical hole, copper current leads installed in the channels of the covers.

Small losses of thermal energy, uniform heating of the heat-resistant pipe in the central part over a length of at least 100 - 250 mm, which is 10-25 internal diameters of the pipe and can serve as a "black body" when calibrating a thermocouple using a pyrometer.

An installation has been developed that makes it possible to solve the problem of accurate temperature measurement, cheaper and simpler calibration of a thermocouple. The unit can be operated in two positions: horizontal and vertical.

Claims (4)

1. High-temperature installation for calibrating thermocouples, containing a housing made of a refractory material, a heater with current leads placed inside the housing, heat-resistant electrical insulators in a protective tube, characterized in that the housing is made of heat-insulating material in the form of a parallelepiped with a through inner cylindrical hole and two end caps , the heater of the unit is made of four emitters connected in series with each other, the heater is installed inside the housing opening, the heater current leads coming from the emitters are laid in the grooves of the end caps and removed from the unit housing away from the heating zone, along the axis of the hole on heat-resistant screens built-in in the end caps, a high-temperature protective tube is fixed with annular heat-resistant disks evenly spaced inside - electrical insulators for fastening thermocouples, the high-temperature tube is made with a ratio of its length to diameter equal to 25. 2. Installation according to claim 1, characterized in that the body is made of heat-resistant material ShVP-1800 K or Ultra Board-2023 K. 3. Installation according to claim 1, characterized in that the emitters are made of UKKM or Uglekon-T material. 4. Installation according to claim 1, characterized in that the insulating disks for fastening thermocouples are made 5-10 mm thick and installed in 50 mm increments.

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