RU95104U1 - INDUCTIVE (TRANSFORMER) PRIMARY MEASURING POSITION TRANSDUCER - Google Patents

Abstract

 1. Inductive (transformer) primary measuring transducer containing a magnetic circuit with an end axial hole, in the cavity of which a winding (windings) is located, and a moving inductor installed in the hole coaxially with the magnetic circuit, characterized in that the inductor has at least one magnetically conducting section, the magnetic circuit is made in the form of a cup-shaped magnetic circuit of a W-shaped cross-section, installed by the internal cavity to the magnetic circuit containing a ferromagnetic flange, the magnetic circuits p Separated by a set-in 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 winding, which has at least one through cut, for example, a radial one, and the magnetic circuits are mated through the external circuit through a dielectric diamagnetic element (s) of the insert. ! 2. The inductive (transformer) primary position measuring transducer according to claim 1, characterized in that the cup-shaped magnetic circuit consists of two magnetically conductive bushings of different diameters, made as a unit with the magnetically conductive flange, the inner sleeve forming the inner circuit of the magnetic circuit, and the outer sleeve with a flange form the external circuit of the magnetic circuit. ! 3. The inductive (transformer) primary measuring transducer according to claim 1, characterized in that the cup-shaped magnetic circuit consists of two magnetically conductive bushings of different diameters and flanges, and the sleeve of a smaller diameter

Description

The utility model relates to measuring technique and can be used as a primary position transmitter.

Known inductive primary measuring transducer containing an inductor, coaxially with a moving magnetically conducting inductor connected to a controlled object, the movement of which causes a change in inductance [1].

A disadvantage of the known device is low sensitivity and a large error in determining the position of the controlled object.

Known inductive primary measuring transducer 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, and an anchor moving in the air gap between the end surfaces of the magnetic circuits, mounted on an inductor mounted in the axial hole of the magnetic circuit, and the anchor is made in the form of a ferromagnetic disk, in the grooves of which is located ring windings connected to variable resistors are provided [2].

A disadvantage of the known device is the small range of movement of the controlled object.

Known inductive primary measuring transducer 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, and an anchor moving in the air gap between the end surfaces of the magnetic circuits, mounted on an inductor mounted in the axial hole of the magnetic circuit, and the anchor is made in the form of a layered magnetic conductive disk, on both sides which is placed electrically conductive diamagnetic pads [3].

A disadvantage of the known device is also a small range of movement of the controlled object.

The inventive utility model is aimed at improving the accuracy of position fixation (detection) and expanding the range of movement of the controlled object.

This is achieved by the fact that the sensing element of the inductive (transformer) primary measuring transducer of position contains a magnetic circuit with an end axial hole in the cavity of which a winding (windings) is located, and a moving inductor installed in the hole coaxially with the magnetic circuit, the inductor has at least one magnetically conducting section, and the magnetic circuit is made in the form of a cup-shaped magnetic circuit of a W-shaped cross section, installed by the internal cavity to the magnetic circuit containing ferromagnetic nth flange, the magnetic cores are separated by an inserted 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 the winding having at least one through cut, for example, a radial one, with the magnetic circuits along the external circuit mated through a dielectric diamagnetic element (s) of the insert.

As an embodiment, it is possible that the cup-shaped magnetic circuit consists of two magnetically conductive bushings of different diameters made as a whole with a magnetically conductive flange, with the inner sleeve forming the internal circuit of the magnetic circuit, and the external sleeve with flange forming the external circuit of the magnetic circuit.

As an embodiment, it is possible that the cup-shaped magnetic circuit consists of two magnetically conductive bushings of different diameters and flanges, the smaller diameter sleeve forms the inner circuit of the magnetic circuit and is made with the flange as a whole, and the larger diameter bush mates with the surface of the flange, forming the external circuit of the magnetic circuit with it .

As an embodiment, it is possible that the cup-shaped magnetic circuit consists of two magnetically conductive bushings of different diameters and flanges, and the smaller diameter bush, mating with the surface of the flange, forms the internal circuit of the magnetic circuit, and the larger diameter bush is made as a whole with the flange, forming an external contour with it magnetic circuit.

As an embodiment, it is possible that the cup-shaped magnetic circuit consists of two magnetically conductive bushings of different diameters and flanges, the smaller diameter bush, mating with the surface of the flange, forms the inner circuit of the magnetic circuit, and the larger diameter bush, mating with the surface of the flange, forms the outer circuit of the magnetic circuit.

As an embodiment, it is possible that the electrically conductive diamagnetic insert element is electrically isolated from the magnetic circuit.

As an embodiment, it is possible that the electrically conductive diamagnetic element of the insert is made in the form of a disk mounted at least on one of the sides or inside the dielectric diamagnetic element of the insert.

As an embodiment, it is possible that the electrically conductive diamagnetic element of the insert consists of sequentially pairing several ring-shaped electrically conductive diamagnetic elements.

As an embodiment, it is possible that the diameter of the electrically conductive diamagnetic element of the insert is equal to the inner diameter of the outer contour of the magnetic circuit.

As an embodiment, it is possible that the dielectric diamagnetic insert element is in the form of a disk.

As an embodiment, it is possible that the dielectric diamagnetic insert element consists of sequentially pairing several ring-shaped dielectric diamagnetic elements.

As an embodiment, it is possible that the inductor coupled to the controlled object is a diamagnetic rod having at least one magnetically conducting portion on the outer cylindrical surface.

As an embodiment, it is possible that the inductor coupled to the controlled object is a magnetically conductive rod having the ability to enter and exit the inner zone of the magnetic circuit blocked by an electrically conductive diamagnetic insert.

As an embodiment, it is possible that the length of the magnetically conducting section of the inductor is not less than the distance between the internal circuits of the magnetic circuits that are interfaced through the insert.

As an embodiment, it is possible that the winding (s) are mounted, for example, on the surface of a conductive diamagnetic insert.

As an embodiment, it is possible that the winding (s) are fixed, for example, on the outer cylindrical surface of the inner sleeve of the magnetic circuit.

As an embodiment, it is possible that the winding (s) are fixed, for example, on the inner cylindrical surface of the outer sleeve of the magnetic circuit.

As an embodiment, it is possible that the winding (s) are fixed, for example, on the inner surface of the magnetic flange.

As an embodiment, it is possible that at least one outer end side of the magnetic circuit is secured with an additional input of the inductor support.

As an embodiment, it is possible that one or more additionally introduced inductor supports are fixed in the gap between the magnetic circuit and the inductor.

As an embodiment, it is possible that a shell is additionally introduced, with which the magnetic circuit is mated along the outer cylindrical surface of the outer contour.

As an embodiment, it is possible that a shell is additionally introduced, with which the magnetic circuit is mated along the outer cylindrical surface of the outer contour and one of the end surfaces.

As an embodiment, it is possible that an additional shell has been introduced, with which the magnetic circuit is mated along the outer cylindrical surface of the outer contour and the end surfaces.

As an embodiment, it is possible that the shell is made of an electrically conductive magnetically conductive material.

As an embodiment, it is possible that the shell is made of weakly conductive or dielectric magnetically conductive material.

As an embodiment, it is possible that the shell is made of an electrically conductive diamagnetic material.

As an embodiment, it is possible that the shell is made of weakly conductive or dielectric diamagnetic material.

As an embodiment, it is possible that the shell has at least one end hole coaxial with the axial hole of the magnetic circuit, with a diameter of at least the diameter of the inductor.

As an embodiment, it is possible that the shell is a support for the inductor.

As an embodiment, it is possible that one or more supports of the inductor are fixed in the gap between the shell and the inductor.

As an embodiment, it is possible that the end surface of the sleeve of a larger diameter mates with the end surface of the flange.

As an embodiment, it is possible that the inner cylindrical surface of the sleeve of a larger diameter mates with the outer cylindrical surface of the flange.

As an embodiment, it is possible that the end surface of the sleeve of a smaller diameter mates with the end surface of the flange.

As an embodiment, it is possible that the outer cylindrical surface of the sleeve of a smaller diameter mates with the inner cylindrical surface of the flange.

As an embodiment, it is possible that one of the magnetically conducting bushings is made integral in the form of a set of ring-shaped elements conjugated along end or cylindrical surfaces.

As an embodiment, it is possible that the magnetically conductive bushings are made integral in the form of a set of ring-shaped elements mating along end or cylindrical surfaces.

As an embodiment, it is possible that the flange is made integral in the form of a set of ring-shaped elements conjugated along end or cylindrical surfaces.

As an embodiment, it is possible that the ring-shaped elements of the insert are electrically isolated from each other.

As an embodiment, it is possible that the cuts of the ring-shaped insert elements coincide.

As an embodiment, it is possible that the cuts of the ring-shaped insert elements do not coincide, and the cut of one ring-shaped element overlaps the electrically conductive diamagnetic sections of the other elements isolated between themselves.

The magnetic circuit of the inductive (transformer) primary measuring transducer, made in the form of a cup-shaped magnetic circuit of W-shaped cross-section, installed by the internal cavity to the magnetic circuit containing the ferromagnetic flange, mating along the external circuit through the dielectric diamagnetic element (s) of the insert, and on the inside through the conductive diamagnetic or conductive diamagnetic and dielectric diamagnetic elements of the insert, has a high sensitivity, ak previous furthermore simplifies mounting diamagnetic electroconductive paste.

The section of the diamagnetic conductive insert allows to reduce ring currents and, accordingly, losses when the magnetic flux of the magnetic circuit is closed through the magnetic circuit, which increases the sensitivity of the primary measuring transducer, since The change in sensor coil inductance increases.

A composite diamagnetic electrically conductive insert, made in the form of a set of ring-shaped elements, electrically isolated from each other, the cuts of which are rotated relative to each other, making it impossible for the magnetic flux to penetrate through the section of the insert when the bulk of the magnetic flux closes through the inductor, which increases the sensitivity of the primary measuring transducer.

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

An analysis of the prior art by the applicant, including a search by patent and scientific and technical sources of information and identification of sources containing information about analogues of the claimed utility model, allowed to establish that the applicant did not find an analogue characterized by features identical to all the essential features of the claimed utility model, and the definition from the list of identified analogues of the prototype as the closest in the totality of the features of the analogue revealed a set of essential in relation to The technical result of the distinguishing features in the claimed object, set forth in the utility model formula, as claimed by the applicant. Therefore, the claimed utility model meets the requirement of "novelty."

To verify the compliance of the claimed utility model with the level requirement, the applicant conducted an additional search for known solutions in order to identify features that match the distinctive features of the claimed utility model, the results of which show that the claimed utility model does not explicitly follow the prior art defined by the applicant , the influence of the transformations provided for by the essential features of the claimed utility model to achieve technical re As a result, in particular, the claimed utility model does not provide for the following transformations:

- the addition of a known means by any known part, attached to it according to known rules, to achieve a technical result, in respect of which the influence of such additions is established;

- replacement of any part of a known product with another known part to achieve a technical result, in respect of which the effect of such a replacement is established;

- the exclusion of any part of the funds with the simultaneous exclusion due to its presence of the function and the achievement of the usual result for this case;

- an increase in the number of elements of the same type to enhance the technical result due to the presence in the tool of just such elements;

- the implementation of a known tool or part of a known material to achieve a technical result due to the known properties of the material;

- the creation of a tool consisting of known parts, the choice of which and the relationship between them are based on known rules, and the technical result achieved in this case is due only to the known properties of the parts of this object and the relationships between them.

Therefore, the claimed utility model meets the requirement of "level".

Figure 1, figure 2 shows the sensing element of the detection sensor in the scope of the independent paragraph 1 of the formula of the utility model. Figure 3, figure 4 and figure 5 disclosed options for pairing a magnetically conductive flange with a magnetically conducting sleeve of a smaller diameter. In Fig.6, Fig.7 and Fig.8 disclosed options for pairing a magnetically conductive flange with a magnetic core of larger diameter. Fig.9-Fig.14 disclosed options for a conductive diamagnetic insert. On Fig and Fig disclosed options for the design of the inductor. On Fig-Fig.20. shows the location of the windings in the cavities of the magnetic circuit. In Fig.21, Fig.22 and Fig.23 presents the design options of the shell. In Fig.24-Fig.28 shows the electrical circuit of the measuring circuits depending on the position of the inductor.

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

The sensor element in Fig. 1 of an inductive primary position transmitter, comprising a magnetic circuit 2 with an end axial hole in the cavity of which a winding 4 is located, and a moving inductor 1. installed in the hole coaxially with the magnetic circuit 2. The inductor 1 has at least one magnetically conducting section. The magnetic circuit 2 is made in the form of a cup-shaped magnetic circuit of a W-shaped cross-section, installed by the internal cavity to the magnetic circuit containing a ferromagnetic flange. The magnetic cores are separated by an inserted 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 inner circuit of the magnetic circuit 2 and winding 4, which has at least one through cut, for example, a radial one. Magnetic cores along the external circuit are interfaced through a dielectric diamagnetic element (s) of the insert.

The sensor element in figure 2 of a transformer primary position transmitter, comprising a magnetic circuit 2 with an end axial hole, in the cavity of which there is a primary winding 4, a secondary winding 5, and a moving inductor 1 installed in the hole coaxially with the magnetic circuit 2. The inductor 1 has at least one magnetically conducting section. The magnetic circuit 2 is made in the form of a cup-shaped magnetic circuit of a W-shaped cross-section, installed by the internal cavity to the magnetic circuit containing a ferromagnetic flange. The magnetic cores are separated by an inserted 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 inner circuit of the magnetic circuit 2 and winding 4, which has at least one through cut, for example, a radial one. Magnetic cores along the external circuit are interfaced through a dielectric diamagnetic element (s) of the insert.

The inner contour of the cup-shaped magnetic circuit in figure 3 is made with a magnetically conducting flange at the same time.

The inner contour of the cup-shaped magnetic circuit in figure 4 is mated with a magnetic flange on the end surface.

The inner contour of the cup-shaped magnetic circuit in FIG. 5 is mated to a magnetic conductive flange on an outer cylindrical surface.

The outer contour of the cup-shaped magnetic circuit in Fig.6 is made with a magnetically conducting flange at the same time.

The outer contour of the cup-shaped magnetic circuit in Fig. 7 is mated to a magnetic flange along an inner cylindrical surface.

The outer contour of the cup-shaped magnetic circuit in Fig. 8 is mated to a magnetic flange on the end surface.

The inductor 1 in Fig. 15 comprises a magnetically conductive 6 and a non-magnetic conductive portion 7.

The inductor 1 in Fig. 16 is a non-magnetically conductive rod 7 having a magnetically-conducting portion 6 on the outer cylindrical surface.

The magnetic circuit 2 in figure 2-1 is mated on the outer cylindrical surface of the external circuit with the shell 8.

The magnetic circuit 2 in FIG. 22 is mated along the outer cylindrical surface of the outer contour and one of the end surfaces with a shell 8.

The magnetic circuit 2 in Fig.23 is mated on the outer cylindrical surface of the outer contour and the end surfaces with a shell 8.

The sensitive element of the inductive type in figure 1 works as follows.

When a harmonic or pulse signal is applied to the winding 4, when the diamagnetic section of the inductor 1 is located in the area of the diamagnetic insert 3, for example, the dielectric, magnetic flux of the windings 4 induces an EMF in the diamagnetic electrically conductive element of the insert 3. The electrical circuit of the measuring circuit is shown in Fig.24 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 insert 3 (R ~ 0). Thus, when in the area of the diamagnetic insert 3 there is a diamagnetic section of the inductor 1, the coil 4 of the sensor and the diamagnetic insert 3 operate as a transformer 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 insert 3, where it is converted into Foucault currents. In this case, the inductance of the 4 L ₀₁ winding tends to zero. Its complex resistance Z ₀₁ becomes equal to Z ₀₁ = r + jωL ₁ , (where ω is the frequency of the supply voltage; r is the active resistance of the winding), which is also small. This mode of operation of the sensing element can be replaced by the circuit shown in Fig.25. In which the resistance of the element 12 is equivalent to the parallel connection of the active resistance of the winding and the internal resistance of the diamagnetic electrically conductive insert 3. Thus, when a non-magnetic conductive portion of the inductor 1 is located in the zone of the diamagnetic insert 3, the complex resistance of the sensitive element is small, and therefore the voltage drop across it is also small .

When moving the inductor 1 associated with the controlled object into the zone of the diamagnetic insert 3, the magnetically conducting section of the inductor 1 enters, the main part of the magnetic flux closes through the inductor 1, the inner circuit of the cup-shaped magnetic circuit 2, the outer circuit of the cup-shaped magnetic circuit, the dielectric diamagnetic element of insert 3 and the air gap between the magnetic circuits , the magnetic conductive flange of the second magnetic circuit and the magnetic conductive portion of the inductor 1. An equivalent circuit of this mode of operation is presented Figure 26. In this case, the total magnetic flux sharply decreases, energy losses also decrease and they can be neglected. The resistance of the sensor becomes equal

Z ₀₂ = r + jωL ₂

In this case, L _{2 is} much larger than L ₁ , and therefore, Z _{02 is} much larger than Z ₀₁ , which corresponds to a larger voltage drop across the sensing element when the magnetically conductive section of the inductor is located in the area of the diamagnetic insert.

Thus, by controlling the voltage drop across the sensitive element, for example, using a voltage divider on the inductive and resistive elements, it is possible to obtain unambiguous information about which section of the inductor is in the zone of the diamagnetic electrically conductive insert 3.

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

When a harmonic or pulse signal is applied to the primary winding 4, when the diamagnetic section of the inductor 1 is located in the zone of the diamagnetic insert 3, for example, the dielectric, magnetic flux of the winding 4 induces an EMF in the diamagnetic electrically conductive insert 3, while almost all the energy of the magnetic field of the winding is transformed into a diamagnetic electrically conductive element of the insert, where it is converted to Foucault currents. The electrical circuit of the measuring circuit is shown in FIG. 27, where 10 is the inductance of the diamagnetic electrically conductive element of insert 3; 11 - internal electrical resistance of insert 3 (R ~ 0). Thus, when the diamagnetic section of the inductor 1 is located in the area of the diamagnetic insert 3, the sensor coil 4 and the diamagnetic insert 3 operate as a transformer in the short circuit mode. In this case, the induction EMF induced in the secondary winding 5 is small.

When moving the inductor 1 associated with the controlled object into the zone of the diamagnetic insert 3, the magnetically conducting section of the inductor 1 enters, the main part of the magnetic flux closes through the inductor 1, the inner contour of the cup-shaped magnetic circuit, the outer circuit of the cup-shaped magnetic circuit, the dielectric diamagnetic insert element and the air gap between the magnetic circuits, magnetically conductive the flange of the second magnetic circuit and the magnetically conducting section of the inductor 1, the diamagnetic insert, as it were, becomes shielded. The electrical circuit of the measuring circuit is shown in Fig. 28. In this case, the energy loss decreases sharply, and the induction EMF induced in the secondary winding 5 increases.

Thus, by controlling the voltage induced in the secondary windings 5 of the sensing element, it is possible to obtain unambiguous information about which section of the inductor is in the area of the diamagnetic electrically conductive insert 3.

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".

Information sources

1. RF patent No. 2221988, MKL 7 G01B 7/14, 2002

2. AC No. 403955, MKL 2 G01d 5/22, 1972

3. AC No. 191380, CL 74b, 8/04, 1967

Claims (23)

1. Inductive (transformer) primary measuring transducer containing a magnetic circuit with an end axial hole, in the cavity of which a winding (windings) is located, and a moving inductor installed in the hole coaxially with the magnetic circuit, characterized in that the inductor has at least one magnetically conducting section, the magnetic circuit is made in the form of a cup-shaped magnetic circuit of a W-shaped cross-section, installed by the internal cavity to the magnetic circuit containing a ferromagnetic flange, the magnetic circuits p Separated by a set-in 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 winding, which has at least one through cut, for example, a radial one, and the magnetic circuits are mated through the external circuit through a dielectric diamagnetic element (s) of the insert. 2. The inductive (transformer) primary position measuring transducer according to claim 1, characterized in that the cup-shaped magnetic circuit consists of two magnetically conductive bushings of different diameters, made as a unit with the magnetically conductive flange, the inner sleeve forming the inner circuit of the magnetic circuit, and the outer sleeve with a flange form the external circuit of the magnetic circuit. 3. The inductive (transformer) primary position measuring transducer according to claim 1, characterized in that the cup-shaped magnetic circuit consists of two magnetically conductive bushings of different diameters and flanges, the smaller diameter sleeve forming the inner circuit of the magnetic circuit and made with the flange as a unit, and the larger sleeve diameter mates with the surface of the flange, forming with it the outer contour of the magnetic circuit. 4. The inductive (transformer) primary position measuring transducer according to claim 1, characterized in that the cup-shaped magnetic circuit consists of two magnetically conductive bushings of different diameters and flanges, the smaller diameter sleeve, mating with the flange surface, forms the inner circuit of the magnetic circuit, and the larger diameter sleeve made with a flange as a whole, forming with it the external circuit of the magnetic circuit. 5. The inductive (transformer) primary position measuring transducer according to claim 1, characterized in that the cup-shaped magnetic circuit consists of two magnetically conductive bushings of different diameters and flanges, the smaller diameter sleeve, mating with the surface of the flange, forms the inner circuit of the magnetic circuit, and the larger diameter sleeve , mating with the surface of the flange, forms the outer contour of the magnetic circuit. 6. The inductive (transformer) primary position measuring transducer according to claim 1, characterized in that the electrically conductive diamagnetic insert element is electrically isolated from the magnetic circuit. 7. The inductive (transformer) primary position transmitter according to claim 1, characterized in that the electrically conductive diamagnetic insert element is made in the form of a disk mounted at least on one of the sides or inside the dielectric insert diamagnetic element. 8. The inductive (transformer) primary position measuring transducer according to claim 1, characterized in that the electrically conductive diamagnetic insert element consists of a series connection of several ring-shaped electrically conductive diamagnetic elements. 9. The inductive (transformer) primary position measuring transducer according to claim 1, characterized in that the diameter of the electrically conductive diamagnetic insert element is equal to the inner diameter of the external circuit of the magnetic circuit. 10. The inductive (transformer) primary position measuring transducer according to claim 1, characterized in that the dielectric insulating element of the insert is made in the form of a disk. 11. The inductive (transformer) primary position measuring transducer according to claim 1, characterized in that the dielectric diamagnetic insert element consists of a series connection of several ring-shaped dielectric diamagnetic elements. 12. The inductive (transformer) primary position measuring transducer according to claim 1, characterized in that the inductor coupled to the controlled object is a diamagnetic rod having at least one magnetically conducting portion on the outer cylindrical surface. 13. The inductive (transformer) primary position measuring transducer according to claim 1, characterized in that the inductor coupled to the controlled object is a magnetically conductive rod having the ability to enter and exit the inner zone of the magnetic circuit blocked by an electrically conductive diamagnetic insert. 14. The inductive (transformer) primary position measuring transducer according to claim 1, characterized in that the length of the magnetically conductive portion of the inductor is not less than the distance between the internal circuits of the magnetic circuits interfaced through the insert. 15. The inductive (transformer) primary position transmitter according to claim 1, characterized in that the winding (s) are mounted, for example, on the surface of a conductive diamagnetic insert. 16. The inductive (transformer) primary position transmitter according to claim 1, characterized in that the winding (s) are mounted, for example, on the outer cylindrical surface of the inner sleeve of the magnetic circuit. 17. The inductive (transformer) primary position transmitter according to claim 1, characterized in that the winding (s) are fixed, for example, on the inner cylindrical surface of the outer sleeve of the magnetic circuit. 18. The inductive (transformer) primary position transmitter according to claim 1, characterized in that the winding (s) are fixed, for example, on the inner surface of the magnetic circuit flange. 19. The inductive (transformer) primary measuring position transmitter according to claim 1, characterized in that at least one outer end side of the magnetic circuit is secured with an additional input of the inductor. 20. The inductive (transformer) primary position measuring transducer according to claim 1, characterized in that one or more additionally introduced inductor supports are fixed in the gap between the magnetic circuit and the inductor. 21. The inductive (transformer) primary position measuring transducer according to claim 1, characterized in that an additional shell is introduced, with which the magnetic circuit is interfaced along the outer cylindrical surface of the external circuit. 22. The inductive (transformer) primary position measuring transducer according to claim 1, characterized in that an additional shell is introduced, with which the magnetic circuit is mated along the outer cylindrical surface of the external circuit and one of the end surfaces. 23. The inductive (transformer) primary position measuring transducer according to claim 1, characterized in that an additional shell is introduced with which the magnetic circuit is interfaced along the outer cylindrical surface of the outer contour and the end surfaces.