RU152832U1 - INDUCTIVE (TRANSFORMER) PRIMARY MEASURING TRANSMITTER OF TASKED VALUE OF TEMPERATURE - Google Patents

Abstract

1. Inductive (transformer) primary measuring transducer of a set value of temperature, containing a magnetic circuit with an end axial hole, made in the form of two cup-shaped magnetic conductors of U-shaped cross-section, installed opposite to the internal cavities, in each of which there is a winding (s), and a magnetic conductive inductor or a non-magnetic conductive inductor having on the outer cylindrical surface a magnetic conductive portion installed in the hole coaxially with the magnetic circuit divided into a boron ring-shaped insert, consisting of at least one dielectric diamagnetic and at least one electrically conductive diamagnetic element that overlaps the magnetic fluxes of the internal circuit of the magnetic circuit and windings, which has at least one through cut, for example a radial one, and cup-shaped magnetic circuits are interfaced along the external circuit through a dielectric diamagnetic element (elements) of an insert, characterized in that the magnetic conductive inductor or the magnetic conductive portion of the non-magnetic conductive heat dyaschego inductor is formed of a material having a given Curie point and the magnetic circuit installed in the area of the overlapped vstavkoy.2. The inductive (transformer) primary measuring transducer of the set temperature value according to claim 1, characterized in that the magnetically conductive inductor or the magnetically conductive portion of the inductor is made of barium metatitanate with a Curie point of + 100 ° C. 3. Inductive (transformer) primary measuring transducer of a preset temperature value according to claim 1, characterized in that the magnetically conductive inductor or

Description

The utility model relates to measuring technique and can be used as a primary measuring transducer of a preset temperature value.

A temperature detector is known [RF Patent No. 90197 RU, IPC G01K 7/38], comprising a housing divided by a heat-insulating gasket into two cavities, in one of which a reed switch (magnetically controlled contact) is fixed, and in the other a thermosensitive element made of ferromagnetic material with a given point Curie and a permanent magnet, the body is made of heat-conducting non-magnetic material, a permanent magnet is fixed at the bottom of the body, the poles of which are fixedly mounted as poles iki directed towards the reed and are made of ferrite to a predetermined Curie point, e.g. HM brand 3000 with a Curie point of 140 ° C, the magnetic flux interacting with the reed contact system at a temperature below the Curie point.

A disadvantage of the known device is the presence of movable elements, which reduces the resource and the accuracy of fixing the set temperature.

A known temperature detector [RF Patent No. 85645 RU, IPC G01K 7/38], comprising a heat-conducting body, a thermosensitive element made of ferromagnetic material with a given Curie point, a permanent magnet and a contact system, for example in the form of a micro switch or reed switch, the thermosensitive element is made in the form of a hollow the ferrite cylinder and is fixed with an end face at the bottom of the heat-conducting body, a permanent magnet is freely mounted on the other end of the cylinder, a spring with a support on the permanent magnet is placed inside the cylinder, and fixed over the magnet A contact system interacting with a magnet at a ferrite temperature above the Curie point is obtained.

A disadvantage of the known device is the presence of movable elements, which reduces the resource and the accuracy of fixing the set temperature.

The closest to the claimed technical solution, the prototype is an inductive (transformer) primary measuring transducer [RF Patent No. 95109 RU, IPC G01B 7/14] containing a magnetic circuit with an end axial hole, made in the form of cup-shaped magnetic circuits of Sh-shaped section, installed counter internal cavities, in each of which there is a winding (s), and an inductor installed in the hole coaxially with the magnetic circuit, having a magnetically conducting part along the outer cylindrical surface current, and cup-shaped magnetic cores on the outer contour are interfaced through the air gap, and along, and on the outside, through an annular electrically conductive non-magnetic conductive blocking magnetic fluxes of the magnetic circuits and windings, an insert having at least one through cut, for example, a radial one.

A disadvantage of the known device is the inability to determine the setpoint temperature.

The purpose of the claimed utility model is to increase the accuracy of control of a given temperature value.

The essence of the claimed technical solution lies in the fact that the inductive (transformer) primary measuring transducer of the set value of temperature, containing a magnetic circuit with an end axial hole, made in the form of two cup-shaped magnetic circuits of W-shaped cross section, installed counter-internal cavities, in each of which there is a winding ( windings), and a magnetically conductive inductor or non-magnetically conductive inductor having a magnetically conductive portion on the outer cylindrical surface, installed in the hole coaxially to the magnetic circuit, separated by a dial-up ring-shaped insert, consisting of at least one dielectric diamagnetic and at least one electrically conductive diamagnetic element that overlaps the magnetic fluxes of the internal circuit of the magnetic circuit and windings, which has at least one through section, for example, a radial one, with cup-shaped magnetic circuits along the external circuit is mated through a dielectric diamagnetic element (s) of the insert characterized in that the magnetically conductive ind A core or a magnetically conductive section of a non-magnetic conductive inductor is made of material with a given Curie point and installed in the area of the magnetic circuit with a covered insert, an inductive (transformer) primary measuring transducer of a given temperature value, characterized in that the magnetically conductive inductor or magnetically conductive section of the inductor is made of barium metatitanate with a Curie + 100 ° C, inductive (transformer) primary measuring transducer setpoint temperature s, characterized in that the magnetically conductive inductor or the magnetically conductive section of the inductor is made of gadolinium with a Curie point of + 16 ° C, the inductive (transformer) primary measuring transducer of the set temperature value, characterized in that the magnetically conductive inductor or the magnetically conductive section of the inductor is made of Geisler alloy (61 % Cu, 26% Mn, 13% Al) with a Curie point of + 330 ° C, inductive (transformer) primary measuring transducer of the set temperature value, characterized in that The conductive inductor or the magnetically conductive portion of the inductor is made of MnP with a Curie point of + 25 ° C.

The goal is achieved in that the inductive (transformer) primary measuring transducer of the set temperature value contains a magnetic circuit with an end axial hole made in the form of a cup-shaped magnetic circuit of U-shaped cross section, installed opposite to the internal cavities, in each of which there is a winding (winding), and a magnetically conductive a circuit or a non-magnetic conductive inductor having on the outer cylindrical surface a magnetic conductive portion installed in the hole coaxially with the magnetic circuit, a divided ring-shaped insert, consisting of at least one dielectric diamagnetic and at least one electrically conductive diagnostic element that overlaps the magnetic fluxes of the internal circuit of the magnetic circuit and windings, which has at least one through cut, for example a radial one, and cup-shaped magnetic circuits are interfaced through the external circuit through a dielectric element (s) of the insert, while the magnetically conductive inductor is the magnetically conductive portion of the non-magnetically conductive heat input The duct is made of material with a given Curie point and is installed in the area of the magnetic circuit with a covered insert.

As an embodiment, it is possible that the magnetically conductive inductor or the magnetically conductive portion of the inductor is made of barium metatitanate with a Curie point of + 100 ° C.

As an embodiment, it is possible that the magnetically conductive inductor or the magnetically conductive portion of the inductor is made of gadolinium with a Curie point of + 16 ° C.

As an embodiment, it is possible that the magnetically conductive inductor or the magnetically conductive portion of the inductor is made of a Geisler alloy (61% Cu, 26% Mn, 13% Al) with a Curie point of + 330 ° C.

As an embodiment, it is possible that the magnetically conductive inductor or the magnetically conductive portion of the inductor is made of MnP with a Curie point of + 25 ° C.

The magnetically conducting section of the inductor made of material with a given Curie point allows you to accurately record the temperature transition of the controlled object through the Curie point.

In various embodiments, the inductive sensitive element by means of a heat-conducting inductor associated with the controlled object, provides information about the temperature of the controlled object in a given area.

The essence of the utility model is illustrated by drawings, which depict:

In FIG. 1, FIG. 2 shows the primary measuring transducer of the set temperature in the volume of the independent paragraph 1 of the formula of the utility model. In FIG. 3, FIG. 4 shows the design of a conductive diamagnetic insert. In FIG. 5 and FIG. 6 discloses design options for the inductor. In FIG. 7 - FIG. 11 shows the electrical circuits of the measuring circuits depending on the temperature of the inductor.

Information confirming the feasibility of implementing the utility model with obtaining the above technical result is as follows.

The sensing element in FIG. 1 of the inductive (transformer) primary measuring transducer of the set value of temperature contains a magnetic circuit 2 with an end axial hole, made in the form of a cup-shaped magnetic circuit of W-shaped cross-section, mounted counter-internal cavities, in each of which there is a winding 4. Magnetic conductive inductor 1 or non-magnetic conductive inductor 1 having on the outer cylindrical surface a magnetically conductive section installed in the hole coaxially to the magnetic circuit 2, section a type-setting ring-shaped insert 3, consisting of at least one dielectric diamagnetic and at least one electrically conductive diamagnetic element that overlaps the magnetic fluxes of the internal circuit of the magnetic circuit 2 and windings 4, which has at least one through cut, for example a radial one, and the cup-shaped magnetic circuits are mated along the external circuit through the dielectric diamagnetic element (s) of the insert 3. A magnetically conductive inductor 1 or a magnetically conductive portion of a non-magnetically conductive heat-conducting and Inductor 1 is made of material with a given Curie point and is installed in the area of the magnetic circuit 2 with a blocked insert 3.

The sensing element in FIG. 2 of the transformer primary measuring transducer of the set value of temperature contains a magnetic circuit 2 with an end axial hole, made in the form of two cup-shaped magnetic circuits of W-shaped cross-section, installed counter-internal cavities, in each of which there is a primary winding 4 and a secondary winding 5. Magnetic conductive inductor 1 or non-magnetic a heat-conducting inductor 1 having on the inner cylindrical surface a magnetically conductive portion installed in the hole coaxially the magnetic circuit 2, separated by a type-setting ring-shaped insert 3, consisting of at least one dielectric diamagnetic and at least one electrically conductive diamagnetic element that overlaps the magnetic fluxes of the internal circuit of the magnetic circuit 2 and windings 4, which has at least one through cut, for example a radial, with cup-shaped magnetic circuits along the external circuit is mated through a dielectric diamagnetic element (s) of the insert 3. Magnetic conductive inductor 1 or magnetic conductive portion non-magnetic The sheath of the heat-conducting inductor 1 is made of material with a given Curie point and is installed in the area of the magnetic circuit 2 with a blocked insert 3.

Inductor 1 in FIG. 5 contains magnetically conductive sections 6 with a given Curie point and a non-magnetically conductive heat-conducting section 7.

Inductor 1 in FIG. 6 is a non-magnetically conductive heat-conducting rod 7 having a magnetically-conducting portion 6 with a predetermined Curie point on the inner cylindrical surface.

The inductive type sensor in FIG. 1 works as follows.

When a harmonic or pulse signal is applied to the windings 4, when the thermomagnetic section 6 of the inductor 1 is located in the zone of the diamagnetic electrically conductive element of the insert 3, for example, at a temperature above the Curie point, the magnetic sweats of the winding 4 do not interact, inducing an EMF in the diamagnetic electrically conductive element of the insert 3. The electrical circuit of the measuring circuit is shown in FIG. 7, where 9 is the model resistance, 10 is the inductance of the diamagnetic electrically conductive element of the insert 3; 11 - internal electrical resistance of the conductive element of the insert 3 (R ~ 0). Thus, when the thermomagnetic section 6 of the inductor 1 is located in the zone of the diamagnetic insert 3 at a temperature above the Curie point, the windings 4 of the sensing element and the electrically conductive element of the insert 3 operate as transformers in the short circuit mode. In this mode, almost all the energy of the magnetic field of the winding 4 is transferred to the electrically conductive diamagnetic element of the insert 3, where it is converted to Foucault currents. In this case, the inductance of the windings 4 L _0l tend to zero. Their complex resistance Z ₀₁ is equal to Z ₀₁ = jωL _0l + r, (where ω is the frequency of the supply voltage; r is the active resistance of the windings), which is also small. Such a mode of operation of the sensing element can be replaced by the circuit shown in FIG. 8. In which the resistance of the element 12 is equivalent to the parallel inclusion of the active resistance of the winding 4 and the internal resistance of the diamagnetic electrically conductive element of the insert 3. Thus, when the thermomagnetic section 6 of the inductor 1 is located in the zone of the insert 3 at a temperature above the Curie point, the complex resistance of the sensitive element is small, and therefore, the voltage drop on it is also of little importance.

When the temperature of the inductor 1 associated with the controlled object decreases, when the thermomagnetic section 6 of the inductor 1 is located in the insertion zone 3 at a temperature below the Curie point, the bulk of the magnetic flux directed counterclockwise through the inductor 1, the inner circuit of the cup-shaped magnetic circuit 2, the outer circuit of the cup-shaped magnetic circuit 2, the dielectric diamagnetic element of the insert 3, the outer circuit of the second cup-shaped magnetic circuit 2, the inner circuit of the second cup-shaped magnetic circuit 2, and thermomagnetic th section 6 of inductor 1. An equivalent circuit of such an operating mode is shown in FIG. 9. In this case, the total magnetic flux sharply decreases, energy losses also decrease and they can be neglected. The inductance of the sensor becomes

where L ₁ , L ₂ - inductance, respectively, of the first and second windings of the sensing element.

Sensor Resistance

In this case, (l ₁ + L ₂ ) is much larger than µL ₁ L ₂ , and therefore, Z _{02 is} much larger than Z ₀₁ , which corresponds to a larger voltage drop across the sensing element when the thermomagnetic section 6 of the inductor is located in the insertion zone 3 1 at temperatures below the Curie point.

Thus, by controlling the voltage drop across the sensing element, for example, using a voltage divider on the inductive and resistive elements, it is possible to obtain unambiguous information about in which predetermined temperature zone the thermomagnetic section 6 of the inductor 1 is located.

The transformer type sensor in FIG. 2 works as follows.

When a harmonic or pulse signal is applied to the primary windings 4 when the thermomagnetic section 6 of inductor 1 is located in the zone of the diamagnetic electrically conductive element of insert 3 at a temperature above the Curie point, the magnetic fluxes of winding 4 do not interact, inducing EMF in the diamagnetic electrically conductive element of insert 3, when In this case, almost all the energy of the magnetic field of the windings is transformed into a diamagnetic electrically conductive element of insert 3, where it is converted to Foucault currents. The electrical circuit of the measuring circuit is shown in FIG. 10, where 10 is the inductance of the diamagnetic conductive element of the insert 3; 11 - internal electrical resistance of the conductive element of the insert 3 (R ~ 0). Thus, when the thermomagnetic section 6 of the inductor 1 is located in the zone of the insert 3 at a temperature above the Curie point, the windings 4 of the sensing element and the diamagnetic electrically conductive element insert 3 operate as transformers in the short circuit mode. In this case, the induction EMF induced in the secondary windings 5 is of little importance.

When the temperature of the heat-conducting inductor 1 associated with the controlled object decreases, when the thermomagnetic section 6 of the inductor 1 is located in the zone of the diamagnetic conductive element of the insert 3 at a temperature below the Curie point, the bulk of the magnetic flux directed counterclockwise through the thermomagnetic section 6 of the inductor 1, the inner circuit is cup-shaped magnetic circuit 2, the external circuit of the cup-shaped magnetic circuit 2, the dielectric diamagnetic element of the insert 3, the external circuit of the second cup-shaped magnet the lead 2, the inner circuit of the second cup-shaped magnetic circuit 2 and the thermomagnetic section of the inductor 1. The insert 3 is shunted by the inductor 1, i.e. the magnetic flux is closed not on the dielectric diamagnetic element of the insert 3, but through the brake-magnetic section 6 of the inductor 1. The electrical circuit of the measuring circuit is shown in FIG. 11. In this case, the energy loss decreases sharply, and the induction EMF induced in the secondary windings 5 increases.

Thus, by controlling the voltage induced in the secondary winding 5 of the sensing element, it is possible to obtain unambiguous information about in which predetermined temperature zone the thermomagnetic section 6 of the inductor 1 is located.

Thus, the above information indicates the fulfillment of the following set of conditions when using the claimed utility model:

- a tool that performs the claimed utility model in its implementation, is intended for use in industry, namely in measuring equipment;

- for the claimed utility model in the form as described in the independent claim, the possibility of its implementation using the means and methods described above or known prior to the priority date is confirmed;

- a tool that embodies the claimed utility model in its implementation, is able to ensure the achievement of a technical result.

Therefore, the claimed utility model meets the requirement of ″ industrial applicability ″.

Claims (5)

1. Inductive (transformer) primary measuring transducer of a set value of temperature, containing a magnetic circuit with an end axial hole, made in the form of two cup-shaped magnetic conductors of U-shaped cross-section, installed opposite to the internal cavities, in each of which there is a winding (s), and a magnetic conductive inductor or a non-magnetic conductive inductor having on the outer cylindrical surface a magnetic conductive portion installed in the hole coaxially with the magnetic circuit divided into a boron ring-shaped insert, consisting of at least one dielectric diamagnetic and at least one electrically conductive diamagnetic element that overlaps the magnetic fluxes of the internal circuit of the magnetic circuit and windings, which has at least one through cut, for example a radial one, and cup-shaped magnetic circuits are interfaced along the external circuit through a dielectric diamagnetic element (elements) of an insert, characterized in that the magnetic conductive inductor or the magnetic conductive portion of the non-magnetic conductive heat dyaschego inductor is formed of a material having a given Curie point and the magnetic circuit installed in the overlapped zone of the insert. 2. The inductive (transformer) primary measuring transducer of the set temperature value according to claim 1, characterized in that the magnetically conductive inductor or the magnetically conductive portion of the inductor is made of barium metatitanate with a Curie point of + 100 ° C. 3. The inductive (transformer) primary measuring transducer of the set temperature value according to claim 1, characterized in that the magnetically conductive inductor or the magnetically conductive section of the inductor is made of gadolinium with a Curie point of + 16 ° C. 4. The inductive (transformer) primary measuring transducer of the set temperature value according to claim 1, characterized in that the magnetically conductive inductor or the magnetically conductive portion of the inductor is made of Geisler alloy (61% Cu, 26% Mn, 13% Al) with a Curie point of + 330 ° C. 5. The inductive (transformer) primary measuring transducer of the set temperature value according to claim 1, characterized in that the magnetically conductive inductor or the magnetically conductive portion of the inductor is made of MnP with a Curie point of + 25 ° C.

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