RU186971U1 - THERMOPHARE WITH HEATING - Google Patents

Abstract

The invention relates to a measurement technique and can be used in thermocouple heating circuits, for example, to determine the speed of a single-phase fluid flow in laminar and turbulent flow regimes. A thermocouple with heating is proposed, in which the heating zone is made of dissimilar materials and separated from the measuring zone by electrically insulating layers. Moreover, the electrical resistance of a section of the heating zone adjacent to the side walls of the thermocouple shell _Rpb is much greater than the resistance of the portion of the heating zone adjacent to the steel _{tube Rp.p} , _Rc.b >> _Rc.p , and the thermoelectric junction is located on the central axis of the thermocouple in the middle of the heating zone. The technical result is to improve the accuracy of determining the temperature of the shell and the reliability of the sensor. 1 il.

Description

Known thermocouple containing thermoelectrodes, on the one hand forming the junction, and on the other through the wiring node, connecting wires connected to the power source and through the wiring node and thermoelectrode wires to the thermo-EMF meter (Patent of Russia 2289107 MPK3 G01K 7/0 Thermopair / A). E. Boltenko, N.N. Kirin, E.A. Boltenko, V.P. Sharov // Application No. 2004123231 dated July 29, 2004, Bulletin No. 34, 2006).

The lack of a thermocouple is that it can be performed under laboratory conditions, when there is no need to protect the thermocouple from the measuring medium (water, steam at high pressures and temperatures).

Known cable thermocouple containing thermoelectrodes, forming a junction, placed in a steel sheath, filled with electrical periclase, closed with a steel tube on the junction side. (Thermoelectric temperature transducers. Theory, practice, development / Under the general editorship of AV Karzhavin, - Ed. 2nd, add. - Obninsk. - 2004. - 84 p.).

The disadvantage is that it is impossible to directly use a thermocouple for heating due to the high resistance of thermoelectrode wires, and the heating zone is always larger than the measurement zone.

A well-known thermocouple with heating, containing thermoelectrode wires and junctions, forming a measuring zone and a heating zone, placed in a steel sheath filled with electrical periclase, closed by a steel plug on the side of the junction, connected to a power source and thermopower meter, the end of the steel sheath is closed with silicone sealant. (Patent of the Russian Federation for useful model 174324 (51) IPC G01K 7/02, (2006.01) Thermocouple with junction heating / EA Boltenko, V.P. Sharov // Application No. 2017102303 from 01/24/2017, published on 11.10.2017. Bull. # 29).

The main disadvantage of a thermocouple with junction heating is that it is difficult to separate the measurement zone from the heating zone during the manufacture of a thermocouple. As a result, the length of the heating zone, and, accordingly, the power allocated to the section of the heating zone is determined with great error.

In addition, it is difficult to completely separate from the noise passing from the source of alternating voltage and, accordingly, to separate the useful signal from the signal coming from the power source.

A thermocouple with heating containing thermoelectrode wires and junctions forming a measuring zone and a heating zone, placed in a steel sheath filled with electrical periclase, closed with a steel plug from the side of the junction connected to the power source and the thermopower meter, is proposed. that the heating zone is made of dissimilar materials, is separated from the measuring zone by electrically insulating layers, and the electrical resistance of the section of the nag zone eva adjacent to the sidewalls of shell thermocouple R _ZB, much more resistance heating zone portion adjacent to the steel tube _z.pr R, R _ZB >> R _z.pr, and a thermoelectric junction disposed on the central axis in the middle zone of the thermocouple heating, where R _z.b - electrical resistance of the heating zone adjacent to the side walls of the thermocouple shell, R _z.pr. - electrical resistance of the heating zone adjacent to the steel _tube R _sp.pr. .

The technical result, which directed the proposed utility model, is to improve the accuracy of determining the temperature of the shell and the reliability of the sensor, which is achieved by the fact that the heating zone is made of dissimilar materials, is separated from the measuring zone by electrically insulating layers, and the electrical resistance of the section of the heating zone adjacent to the side the walls of the thermocouple shell R _z.b are much greater than the resistance of the heating zone section adjacent to the steel _tube R _z.pr , R _z.b >> R _z.pr , and the thermoelectric junction p It is placed on the central axis of the thermocouple in the middle of the heating zone, where R _sb is the electrical resistance of the heating zone adjacent to the side walls of the thermocouple shell, R _cpr. - electrical resistance of the heating zone adjacent to the steel _tube R _sp.pr. .

The achievement of the technical result, which consists in improving the accuracy of determining the temperature of the shell, is due to the fact that the electrical resistance of the heating zone section adjacent to the side walls of the thermocouple shell _Rcb is much greater than the resistance of the portion of the heating zone adjacent to the steel _{tube Rc.} , R _z.b >> R _z.pr , and the thermoelectric junction is located on the central axis of the thermocouple in the middle of the heating zone, where R _z.b is the electrical resistance of the heating zone adjacent to the side walls of the thermocouple shell, R _s.pr. - electrical resistance of the heating zone adjacent to the steel _tube R _sp.pr. .

Thermocouple with heating is used to determine the rate (flow) of the coolant in the pipe. The definition of speed is as follows. Measure the temperature of the coolant T_t, heat the thermocouple from the current source, measure the temperature T_n thermocouples, determine T_n.st.- the temperature of the outer wall of the thermocouple shell, determine the difference ΔT = T_n.st.-T_t, determine the velocity of the coolant on the basis of the previously obtained dependences connecting the velocity of the coolant with the physical properties of the coolant, the geometry of the section in which the measurement is carried out, heat flux from the surface of the thermocouple shell where T_n - temperature of the thermocouple installed in the center of the heating zone, T_t - coolant temperature. T_n.st.- the temperature of the outer wall of the thermocouple shell, W - the velocity of the coolant.

The dependence connecting the velocity of the coolant with the physical properties of the coolant, the geometry of the area in which the velocity is measured, the heat flux from the surface of the outer wall of the shell, has the following form:

q is the heat flux from the surface of the outer wall of the thermocouple W / m ² ;

q = W / F, where F is the surface of the outer wall of the thermocouple shell; λ _f - heat transfer coefficient of the heat carrier W / m ° С; d is the diameter of the outer wall of the thermocouple shell m; ν _f — kinematic viscosity of the coolant, m ² / s; Pr is the Prandtl criterion; A, n, n ₁ , - the coefficients determined on the basis of experimental data.

Dependence obtained on the basis of criterion dependence:

, Прандтля Pr=ν_f/a_f, Рейнольдса,where Nu is the Nusselt criterion -

, Prandtl Pr = ν _f / a _f , Reynolds,

Re = Wd / ν _f , α is the heat transfer coefficient from the outer wall of the shell. As can be seen from (1) the accuracy of determining the speed (flow) depends largely on the accuracy of determining q and ΔT = T _n.st. -T _t . The accuracy of determining the temperature of the thermocouple shell T _n increases due to the fact that the electrical resistance of the section of the heating zone adjacent to the side walls of the thermocouple shell R _cb is much greater than the resistance of the section of the heating zone adjacent to the steel cork R _c.pr , R _c.b >> R _z.pr , and thermoelectric junction is located on the central axis of the thermocouple in the middle of the heating zone.

In our case, the section of the heating zone adjacent to the side walls of the thermocouple shell _RW.b is made of nichrome, the section of the heating zone adjacent to the steel _{tube RW.p.} made of copper. Condition R _z.b >> R _z.pr. complied with. The fulfillment of this condition makes it possible to virtually eliminate the generation of heat in the area adjacent to the steel cork, i.e. exclude heat not involved in the determination of heat transfer coefficient and speed, correctly determine the heat flux from the shell, accurately determine α - heat transfer coefficient from the surface of the heating zone, and, consequently, determine the velocity of the coolant accurately enough.

The placement of the thermoelectric junction on the central axis of the thermocouple in the middle of the heating zone allows to accurately determine the temperature difference through the shell, electrical insulation and, accordingly, the temperature of the outer wall of the shell T _n . _Art . = T _n + ΔT _Art. + ΔT _email ,

where t _n . _st - the temperature of the outer wall of the shell, T _n - the temperature in the center of the heating zone, ΔT _st - the temperature difference across the wall of the shell ,. ΔT _el., - temperature difference in the layer of electrical insulation. The achievement of the technical result, which consists in improving the reliability of the sensor, is ensured by the fact that the heating zone is separated from the measuring zone by electrically insulating layers, and the end of the steel shell is closed with silicone sealant. Fulfillment of these conditions allows to exclude the closure to the shell, excludes penetration of moisture from the environment into the periclase.

FIG. 1 shows a schematic representation of a thermocouple with heating. Thermocouple with heating consists of thermoelectrode wires 1, a junction of thermocouple 2, formed by thermoelectrodes made of thermoelectrode materials chromel - alumel. Thermoelectrode wires 1, junction 2 are placed in a steel sheath 3. A heating zone consisting of a heating section adjacent to the sheath 9 and a heating section adjacent to the steel plug 10 is also placed into the steel sheath 3. The heating zone, including sections 9 and 10, connected to the power source 5. The measuring zone, including thermoelectrode wires and junctions, is connected to the thermopower meter 6. The measurement zone and the heating zone are placed in a steel sheath 3 filled with electrical periclase 8. The steel sheath is closed steel Coy 4. The heating zone is made of nichrome - portion 9 and copper - portion 10 is separated from the measuring zone electrically insulating layers 11 and electrical periclase 8.

Thermocouple with heating works as follows. The thermocouple is placed in the channel, where the velocity of the coolant is measured (it is set normally to the incident flow, or towards the flow). Measure the temperature of the coolant. Heat the heating zone by passing current from the power source. Maintain and fix the current through the heating zone at a certain fixed level. Measure the temperature of the heating zone T _n , determine by calculation the heat flux from the outer wall of the thermocouple shell and the temperature of the outer wall of the shell T _n . _Art . Next, according to (1) we determine the speed W and the coolant flow in the channel.

As an example, consider the measurement of the velocity of water in a pipe. A thermocouple was used to measure the velocity of water in a pipe. Thermocouple was placed normally flow. The resistance of the heating zone is 0.3-0.5 ohm, the junction is made of thermoelectrodes chromel alumel.

The current through the heating zone varied in the range of 4–5 A. Measurements showed that the thermocouple makes it possible to create heat flux from the outer wall of the shell q = 150–200 kW / m ² , which ensures high sensitivity in measuring the velocity in the range of 1–3 m / s.

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