RU2288478C2 - Transducer for controlling position in three-step mode - Google Patents

Abstract

FIELD: electric engineering.

SUBSTANCE: device has two additional reference members. Circuit technique versions in connecting reference members in the circuit for measuring object under control are shown depending on the connection mode. The first version involves connecting the first and the second leads of the first reference member to cathode (anode) of the first diode and to anode (cathode) of the third diode, respectively. The first and the second reference member leads of the second reference member are connected to cathode (anode) of the fourth diode and to anode (cathode) of the second diode, respectively.

EFFECT: wide range of functional applications.

16 cl, 11 dwg

Description

The invention relates to measuring technique and is intended to obtain digital information about the three-position position of the controlled object by converting the modules of the complex resistances or mutual inductance of the parametric primary position transducers into an active signal.

A known sensor for measuring displacement, comprising a unit consisting of two independent inductive (transformer) primary measuring transducers, the complex resistance (mutual inductance) of which changes when the controlled object is moved, and a secondary measuring transducer, the first and second outputs of which are connected respectively to the first and second inputs of the block of primary measuring transducers, the first and second outputs of which are connected respectively to the first and second inputs a secondary transducer having first and second information outputs and containing a time-varying signal source, for example, harmonic or pulsed, the first and second terminals of which are connected to the first and second outputs of the secondary transducer, respectively, whose first input is connected to the anode (cathode) of the first diode and the cathode (anode) of the second diode, the anode (cathode) of which is connected to a common bus, to the second terminal of the source, to the first terminals of the first and second resistors, to to the conclusions of the first and second capacitors and to the anode (cathode) of the third diode, the cathode (anode) of which is connected to the second input of the secondary transducer and the anode (cathode) of the fourth diode, the cathode (anode) of the first diode is connected to the first information output of the secondary transducer and with the second terminals of the first resistor and capacitor, the cathode (anode) of the fourth diode is connected to the second information output of the secondary measuring transducer and with the second terminals of the second resistor and capacitor [1 ].

A disadvantage of the known device, when used as a position sensor, is the dependence of the result of converting into an electrical signal the values and changes in the value of the complex resistance of the first (second) of the two inductive primary transducers or position when the complex resistance of the second (first) primary transducer changes when the inductor moves .

A known sensor for measuring displacement, comprising a unit consisting of two independent inductive (transformer) primary measuring transducers, the complex resistance (mutual inductance) of which changes when the controlled object is moved, and a secondary measuring transducer, the first and second outputs of which are connected respectively to the first and second inputs of the block of primary measuring transducers, the first and second outputs of which are connected respectively to the first and second inputs a secondary transducer having first and second information outputs and containing a time-varying signal source, for example, harmonic or pulsed, the first and second terminals of which are connected to the first and second outputs of the secondary transducer, respectively, whose first input is connected to the anode (cathode) of the first diode and the cathode (anode) of the second diode, the anode (cathode) of which is connected to the second information output of the secondary measuring transducer and the first output the second capacitor, the second terminal of which is connected to a common bus, the second terminal of the source and the second terminal of the first capacitor, the first terminal of which is connected to the first information output of the secondary measuring transducer and the anode (cathode) of the third diode, the cathode (anode) of which is connected to the second input of the secondary the measuring transducer and the anode (cathode) of the fourth diode, the cathodes (anodes) of the first and fourth diodes are connected respectively to the anodes (cathodes) of the third and second diodes [2].

A disadvantage of the known device, when used as a position sensor, is the dependence of the result of converting into an electrical signal the values and changes in the value of the complex resistance of the first (second) of the two inductive primary transducers or position when the complex resistance of the second (first) primary transducer changes when the inductor moves .

The basis of this invention is the task of obtaining digital information about the three-position position of the controlled object using two independent primary position transducers.

This goal is achieved by the fact that the sensor for three-position control, containing a unit consisting of two independent inductive (transformer) primary position transducers, the complex resistance (mutual inductance) of which changes when the controlled object is moved, and a secondary converter, the first and second outputs of which connected respectively to the first and second inputs of the block of primary converters, the first and second outputs of which are connected respectively to the first and second the inputs of the secondary converter having the first and second information outputs and containing a source of a time-variable signal, for example, harmonic or pulsed, the first and second terminals of which are connected to the first and second outputs of the secondary converter, respectively, whose first input is connected to the anode (cathode) of the first diode and the cathode (anode) of the second diode, the anode (cathode) of which is connected to the first output of the second resistor, to the second information output of the secondary converter and to the first output a second capacitor, the second terminal of which is connected to the second terminal of the second resistor, with the second output of the secondary converter, a common bus, the second terminal of the first resistor and the second terminal of the first capacitor, the first terminal of which is connected to the first terminal of the first resistor, to the first information output of the secondary converter, and two sample elements, the first and second the first terminals of the first model element are connected respectively to the cathode (anode) of the first diode and to the anode (cathode) of the third diode, the first and second outputs of the second model element are connected respectively to the cathode (anode) of the fourth diode and to the anode (cathode) of the second diode.

In this device, the implementation of two model elements is proposed so that the first and second model element are resistors (inductances).

Additionally, in this device, the implementation of two model elements is proposed so that the first and second model element, respectively, are a resistor (inductance) and inductance (resistor).

In various versions of the model elements, each of them provides a reference voltage for the opposite, in relation to its own, shoulder of the secondary Converter.

This device proposes the execution of a block of primary position transducers so that the block contains two independent inductive primary position transducers, the first conclusions of which are connected to the first input of the block, the second outputs of the first and second independent inductive primary position transducers, respectively, are connected to the first and second outputs of it.

This device proposes the execution of a block of primary position transducers so that the block contains two independent transformer primary position transducers, each of which contains primary and secondary windings, and the beginnings (ends) of the primary windings of the first and second independent transformer primary position converters are connected to the second input of the block primary position transducers, the first input of which is connected to the ends (beginnings) of the primary windings of the first and second independent first position transducers, the beginning (end) of the secondary winding of the first primary position transducer is connected to the first output of the block of primary position transducers, the second output of which is connected to the beginning (end) of the secondary winding of the second independent primary position transducer, the end (beginning) of which secondary winding is connected to the end (beginning) of the secondary winding of the first primary position transducer and the second input of the block of independent primary position transducers.

Additionally, in this device, it is proposed that the block of primary position transducers be implemented so that the block contains two independent transformer primary position transducers, each of which contains a primary and secondary winding, with the beginning (end) of the primary winding of the first and the beginning (end) of the primary winding of the second independent transformer primary position transducers are connected to the second input of the block of primary position transducers, the first input of which is connected to the end (beginning) of the primary of the first winding and the end (beginning) of the primary winding of the second independent primary position transducers, the end (beginning) of the secondary winding of the first primary position transducer is connected to the first output of the block of primary position transducers, the second output of which is connected to the beginning (end) of the secondary winding of the second independent primary transducer position, the end (beginning) of the secondary winding of which is connected to the beginning (end) of the secondary winding of the first primary position transmitter and the second input independent unit of transducers position.

Additionally, in this device, it is proposed that the block of primary position transducers be implemented so that the block contains two independent transformer primary position transducers, each of which contains a primary and secondary winding, with the beginning (end) of the primary winding of the first and the end (beginning) of the primary winding of the second independent transformer primary position transducers are interconnected, the end (beginning) of the primary winding of the first and the beginning (end) of the primary winding of the second independent transform primary position transducers are connected respectively to the first and second inputs of the primary position transducers block, the first and second outputs of which respectively connect the beginning (end) of the secondary winding of the first and the beginning (end) of the second winding of the second independent transformer primary position transducers, at which the ends (begin ) secondary windings are connected to the second input of the block of primary position transducers.

Additionally, in this device, it is proposed that the block of primary position transducers be implemented so that the block contains two independent transformer primary position transducers, each of which contains a primary and secondary winding, with the beginning (end) of the primary winding of the first and the end (beginning) of the primary winding of the second independent transformer primary position transducers are interconnected, the end (beginning) of the primary winding of the first and the beginning (end) of the primary winding of the second independent transformer The primary position transducers are connected respectively to the first and second inputs of the block of primary position transducers, to the first and second outputs of which respectively the end (beginning) of the secondary winding of the first and the beginning (end) of the second winding of the second independent transformer primary position transducers, respectively, are connected ( end) and end (beginning) of the secondary windings are connected to the second input of the block of primary position transducers.

In various embodiments, two independent inductive or transformer primary position transducers by means of an inductor connected to the controlled object, together with the proposed secondary converter, provide information on the three positions of the controlled object.

This goal is achieved by the fact that the sensor for three-position control, containing a unit consisting of two independent inductive (transformer) primary position transducers, the complex resistance (mutual inductance) of which changes when the controlled object is moved, and a secondary converter, the first and second outputs of which connected respectively to the first and second inputs of the block of primary converters, the first and second outputs of which are connected respectively to the first and second the inputs of the secondary converter, which contains a source of a time-variable signal, for example, harmonic or pulse, the first and second terminals of which are connected to the first and second outputs of the secondary converter, respectively, the first input of which is connected to the anode (cathode) of the first diode and the cathode (anode) of the second a diode whose anode (cathode) is connected to the first output of the second resistor, the second information output of the secondary converter is connected to the first output of the second capacitor, the second output of which connected to the second terminal of the second resistor, to the second output of the secondary converter, to the common bus, to the second terminal of the first resistor and to the second terminal of the first capacitor, the first terminal of which is connected to the first information output of the secondary converter and the cathode (anode) of the first diode, the first terminal the first resistor is connected to the anode (cathode) of the third diode, the cathode (anode) of which is connected to the second input of the secondary converter and the anode (cathode) of the fourth diode, the cathode (anode) of which is connected to the first terminal to the second capacitor, two reference elements are introduced, the first and second terminals of the first reference element are connected respectively to the cathode (anode) of the first diode and to the anode (cathode) of the third diode, the first and second terminals of the second reference element are connected to the cathode (anode) of the fourth diode and to the anode (cathode) of the second diode.

In this device, the implementation of two model elements is proposed so that the first and second model element are resistors (inductances).

Additionally, in this device, the implementation of two model elements is proposed so that the first and second model element, respectively, are a resistor (inductance) and inductance (resistor).

In various versions of the model elements, each of them provides a reference voltage for the opposite, in relation to its own, shoulder of the secondary Converter.

This device proposes the execution of a block of primary position transducers so that the block contains two independent inductive primary position transducers, the first outputs of which are connected to the first input of the block, the second outputs of the first and second independent inductive primary position transducers, respectively, are connected to the first and second outputs of it.

This device proposes the execution of a block of primary position transducers so that the block contains two independent transformer primary position transducers, each of which contains primary and secondary windings, and the beginnings (ends) of the primary windings of the first and second independent transformer primary position converters are connected to the second input of the block primary position transducers, the first input of which is connected to the ends (beginnings) of the primary windings of the first and second independent first position transducers, the beginning (end) of the secondary winding of the first primary position transducer is connected to the first output of the block of primary position transducers, the second output of which is connected to the beginning (end) of the secondary winding of the second independent primary position transducer, the end (beginning) of which secondary winding is connected to the end (beginning) of the secondary winding of the first primary position transducer and the second input of the block of independent primary position transducers.

Additionally, in this device, it is proposed that the block of primary position transducers be implemented so that the block contains two independent transformer primary position transducers, each of which contains a primary and secondary winding, with the beginning (end) of the primary winding of the first and the beginning (end) of the primary winding of the second independent transformer primary position transducers are connected to the second input of the block of primary position transducers, the first input of which is connected to the end (beginning) of the primary of the first winding and the end (beginning) of the primary winding of the second independent primary position transducers, the end (beginning) of the secondary winding of the first primary position transducer is connected to the first output of the block of primary position transducers, the second output of which is connected to the beginning (end) of the secondary winding of the second independent primary transducer position, the end (beginning) of the secondary winding of which is connected to the beginning (end) of the secondary winding of the first primary position transmitter and the second input independent unit of transducers position.

Additionally, in this device, it is proposed that the block of primary position transducers be implemented so that the block contains two independent transformer primary position transducers, each of which contains a primary and secondary winding, with the beginning (end) of the primary winding of the first and the end (beginning) of the primary winding of the second independent transformer primary position transducers are interconnected, the end (beginning) of the primary winding of the first and the beginning (end) of the primary winding of the second independent transform primary position transducers are connected respectively to the first and second inputs of the primary position transducers block, the first and second outputs of which respectively connect the beginning (end) of the secondary winding of the first and the beginning (end) of the second winding of the second independent transformer primary position transducers, at which the ends (begin ) secondary windings are connected to the second input of the block of primary position transducers.

Additionally, in this device, it is proposed that the block of primary position transducers be implemented so that the block contains two independent transformer primary position transducers, each of which contains a primary and secondary winding, with the beginning (end) of the primary winding of the first and the end (beginning) of the primary winding of the second independent transformer primary position transducers are interconnected, the end (beginning) of the primary winding of the first and the beginning (end) of the primary winding of the second independent transformer The primary position transducers are connected respectively to the first and second inputs of the block of primary position transducers, to the first and second outputs of which respectively the end (beginning) of the secondary winding of the first and the beginning (end) of the second winding of the second independent transformer primary position transducers, respectively, are connected ( end) and end (beginning) of the secondary windings are connected to the second input of the block of primary position transducers.

In various embodiments, two independent inductive or transformer primary position transducers by means of an inductor connected to the controlled object, together with the proposed secondary converter, provide information on the three positions of the controlled object.

The 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 invention, allowed to establish that there is currently no analogue characterized by features identical to all the essential features of the claimed invention, and the definition of 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 usmat ivaemomu applicant technical result in the distinguishing features of the claimed subject set out in the claims. Therefore, the claimed invention meets the requirement of "novelty."

To verify the conformity of the claimed invention to the requirements of the inventive step, the applicant conducted an additional search for known solutions in order to identify features that match the distinctive features of the claimed invention, the results of which show that the claimed invention does not explicitly follow from the prior art defined by the applicant, not identified transformations to achieve a technical result, provided as essential features of the claimed The following transformations are not envisaged as essential features for taking, in particular, the claimed invention:

- 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 invention meets the requirement of "inventive step".

Figure 1 shows a sensor for three-position control within the scope of independent claim 1. Figure 2, figure 3 and figure 4 disclosed some variants of the block of primary position transducers. In Fig.5, Fig.6 (Fig.7, Fig.8) schematically shows the location of the central magnetic (central non-magnetic) section of the inductor (the magnetic section is shaded) having a shorter or larger length "b" compared to the distance "a" between the first and second primary position transducers. In Fig.9 and Fig.10, respectively, three zones of unique position control are shown. Their difference lies in the fact that while maintaining the length of the inner zone equal to "c + d" (see Fig. 5, Fig. 6, Fig. 7, Fig. 8), the length "b" of the side zones in Fig. 10 ( which corresponds to Fig.6, Fig.8) more than in Fig.9 (which corresponds to Fig.5, Fig.7), the value of "c + d". Thus, by varying the distance "a" between the primary transducers, the length "b" of the magnetic or non-magnetic portion, "a-b = c + d" (Fig. 5, Fig. 7) or "b-a = c + d" ( Fig.6, Fig.8), you can set the necessary three zones of position control. Figure 11 shows the sensor for three-position control within the scope of independent claim 9.

Information confirming the possibility of carrying out the invention with obtaining the above technical result are as follows.

The sensor for three-position position control in figure 1 contains a block 1, consisting of two independent inductive (transformer) primary position transducers, the complex resistance (mutual inductance) of which changes when the controlled object is moved, and a secondary transducer 2, the first and second outputs of which are connected respectively with the first and second inputs of block 1 of the primary converters, the first and second outputs of which are connected respectively to the first and second inputs of the secondary converter call 2, having the first 3 and second 4 information outputs and containing a source 5 of a time-variable signal, for example a harmonic or pulse, the first and second terminals of which are connected to the first and second outputs of the secondary transducer 2, respectively, the first input of which is connected to the anode (cathode) the first 6 diodes and the cathode (anode) of the second 7 diode, the anode (cathode) of which is connected to the first output of the second 8 resistor, to the second 4 information output of the secondary Converter 2 and to the first output of the second 9 condensate RA, the second terminal of which is connected to the second terminal of the second 8 resistor, with the second output of the secondary converter 2, a common bus 10, the second terminal of the first 11 resistor and the second terminal of the first 12 capacitor, the first terminal of which is connected to the first terminal of the first 11 resistor, to the first 3 the information output of the secondary converter and to the anode (cathode) of the third 13 diode, the cathode (anode) of which is connected to the second input of the secondary converter 2 and the anode (cathode) of the fourth 14 diode, the first and second conclusions of the first 15 reference element They are connected respectively to the cathode (anode) of the first 6 diodes and to the anode (cathode) of the third 13 diodes, the first and second leads of the second 16 reference element are connected respectively to the cathode (anode) of the fourth 14 diodes and to the anode (cathode) of the second 7 diodes.

The block of primary transducers of position 1 of the sensor of FIG. 2 contains an inductor 17 located inside or outside of two independent inductive primary transducers of position 18 and 19, the first terminals of which are connected to the first input of block 1, to the first and second outputs of which are connected respectively the second terminals of the first 18 and a second 19 independent inductive primary position transducers.

The block of primary transducers of the position 1 of the sensor of FIG. 3 contains an inductor 17 located inside or outside of two independent transformer primary transducers of position 18 and 19, each of which contains primary and secondary windings 20, 21 and 22, 23, and the first conclusions of the primary windings 20 and 22 of the first 18 and second 19 independent transformer primary position transducers are connected to the first input of the primary transducer block 1, the second input of which is connected to the second terminals of the primary windings 20 and 22 of the first 18 of the second 19 independent primary transducers, the first terminal of the secondary winding 21 of the first 18 primary position transducer is connected to the first output of the primary transducer block 1, the second output of which is connected to the first terminal of the secondary winding 23 of the second 19 independent primary transducer, the second terminal of the secondary winding 23 of which is connected to the second the output of the secondary winding 21 of the first 18 primary position transducer and the second input of the block of independent primary position transducers 1.

The block of primary transducers of the position 1 of the sensor of FIG. 4 contains an inductor 17 located inside or outside of two independent transformer primary transducers of position 18 and 19, each of which contains a primary and secondary windings 20, 21 and 22, 23, and the first output of the primary winding 20 the first 18 and second terminal of the primary winding 22 of the second 19 independent transformer primary position transducers are interconnected, the second terminal of the primary winding 20 of the first 18 and the first terminal of the primary winding 22 of the second 19 are independent of the transformer primary position transducers are connected respectively to the first and second inputs of the primary transducer block 1, the first and second outputs of which are respectively connected to the first terminals of the secondary windings 21 and 23 of the first 18 and second 19 independent transformer primary position converters, in which the second terminals of the secondary windings 21 and 23 are connected to the second input of the block of primary position transducers 1.

The sensor for three-position position control in FIG. 11 contains a block 1, consisting of two independent inductive (transformer) primary position transducers, the complex resistance (mutual inductance) of which changes when the controlled object is moved, and a secondary transducer 2, the first and second outputs of which are connected respectively with the first and second inputs of block 1 of the primary converters, the first and second outputs of which are connected respectively to the first and second inputs of the secondary converter call 2, having the first 3 and second 4 information outputs and containing a source 5 of a time-variable signal, for example a harmonic or pulse, the first and second terminals of which are connected to the first and second outputs of the secondary transducer 2, respectively, the first input of which is connected to the anode (cathode) the first 6 diodes and the cathode (anode) of the second 7 diodes, the anode (cathode) of which is connected to the first output of the second 8 resistor, the second 4 information output of the secondary Converter 2 is connected to the first output of the second 9 con a sensor, the second output of which is connected to the second terminal of the second 8 resistor, to the second output of the secondary converter 2, to the common bus 10, to the second terminal of the first 11 resistor and to the second terminal of the first 12 capacitor, the first terminal of which is connected to the first 3 information output of the secondary converter 2 and the cathode (anode) of the first 6 diodes, the first output of the first 11 resistor is connected to the anode (cathode) of the third 13 diode, the cathode (anode) of which is connected to the second input of the secondary transducer 2 and the anode (cathode) of the fourth 14 diode, the anode (anode) of which is connected to the first terminal of the second 9 capacitor, the first and second terminals of the first 15 model element are connected respectively to the cathode (anode) of the first 6 diode and to the anode (cathode) of the third 13 diode, the first and second terminals of the second 16 model element are connected respectively, to the cathode (anode) of the fourth 14 diode and to the anode (cathode) of the second 7 diode.

The secondary Converter in figure 1 with the block of primary sensors in figure 2 works as follows.

When a time-variable signal is supplied from the output of source 5 to a positive half-cycle, the current flows through the following circuits: the first - the first terminal of source 5, winding 18 of the first primary position transducer, diode 6, element 15, resistor 11 and capacitor 12 connected in parallel, common bus 10 the second clip of the source 5; the second is the first clamp of the source 5, the winding 19 of the first primary position transducer, diode 14, element 16, the resistor 8 and the capacitor 9 are connected in parallel, the common bus 10, the second clamp of the source 5. Current flows through the following circuits in the negative half-cycle: the first - the second clamp source 5, common bus 10, parallel connected resistor 11 and capacitor 12, diode 13, winding 19 of the first primary position transducer, first clip of source 5; the second is the second terminal of the source 5, the common bus 10, the resistor 8 and the capacitor 9 connected in parallel, the diode 7, the winding 18 of the first primary position transmitter, the first source terminal 5. The capacitors 12 and 9 respectively generate voltages V1, V2 relative to the common bus 10. The values and polarity of these voltages depend on the position of the magnetically conducting section of the inductor 17 located on the inner or outer side of the primary position transducers 18 and 19. Let it be in the initial state, as shown in FIG. 5 (FIG. 6, FIG. 7, FIG. 8) to the complex resistance of the primary position transducer 18 is approximately equal to the complex resistance of the primary position transducer 19, since the non-magnetic (magnetically conductive, magnetically conductive, non-magnetic) portion of the inductor 17 is located in the area of the primary converters 18 and 19. This leads to the fact that the first information output 3 of the secondary converter V1 <0 (V1 <0, V1 <0, V1 <0) and at the second information output 4 of the secondary converter V2 <0 (V2 <0, V2 <0, V2 <0). When moving the inductor 17 in Fig. 5 to the left (in Fig. 6 to the right, in Fig. 7 to the right, in Fig. 8 to the left), a magnetically conducting (non-magnetic, non-magnetic, magnetic) section of the inductor 17, the complex resistance of the primary converter 18 sharply increases (decreases, decreases, increases), while the complex resistance of the primary converter 19 does not change, which means that the value and polarity of VI and V2 change, i.e. at the first information output 3 of the secondary converter V1 <0 (V1> 0, V1> 0, V1 <0) and at the second information output 4 of the secondary converter V2> 0 (V2 <0, V2 <0, V2> 0). When moving the inductor 17 in Fig. 5 to the right (in Fig. 6 left, in Fig. 7 left, in Fig. 8 right) in the area of the primary transducer 19, a magnetically conductive (non-magnetic, non-magnetic, magnetically conductive) section of the inductor 17 is supplied, the complex resistance of the primary transducer 19 sharply increases (decreases, decreases, increases), while the complex resistance of the primary transducer 18 does not change, which means that the value and polarity of V1 and V2 change, i.e. at the first information output 3 of the secondary converter V1> 0 (V1 <0, V1 <0, V1> 0) and at the second information output 4 of the secondary converter V2 <0 (V2> 0, V2> 0, V2 <0).

The secondary Converter in figure 1 with counterclockwise secondary windings of the block of primary converters in figure 3 works as follows.

When a harmonic or pulse signal is supplied from the output of source 5 to a positive half-cycle, the current flows through the circuits: the first - the first terminal of the source 5, the primary winding 20 of the first 18 primary position transmitter, the common bus 10, the second terminal of the source 5; the second is the first clamp of the source 5, the primary winding 22 of the second 19 primary position transmitter, the common bus 10, the second clamp of the source 5; the third is the first terminal of the secondary winding 21 of the first 18 primary position transducer, diode 6, element 15, a resistor 11 and a capacitor 12 connected in parallel, a common bus 10, the second terminal of the secondary winding 21 of the first 18 primary position transducer; the fourth is the first terminal of the secondary winding 23 of the second 19 primary position transducer, diode 14, element 16, a resistor 8 and capacitor 9 connected in parallel, a common bus 10, the second terminal of the secondary winding 23 of the second 19 primary position transducer. In the negative half-cycle, the current flows through the following circuits: the first - the second terminal of the source 5, the common bus 10, the primary winding 20 of the first 18 primary position transmitter, the first terminal of the source 5; the second is the second clamp of the source 5, the common bus 10, the primary winding 22 of the first 19 primary position transmitter, the first clamp of the source 5; the third - the second terminal of the secondary winding 21 of the first 18 primary position transducer, a common bus 10, parallel connection of the resistor 8 and the capacitor 9, diode 7, the first terminal of the secondary winding 21 of the first 18 primary position transducer; the fourth is the second terminal of the secondary winding 23 of the second 19 primary position transmitter, the common bus 10, the resistor 11 and the capacitor 12, diode 13 connected in parallel, the first terminal of the secondary winding 23 of the second 19 primary position converter. Voltages V1, V2 are formed on the capacitors 12 and 9, respectively, with respect to the common bus 10. The value and polarity of these voltages depends on the position of the magnetically conducting section of the inductor 17 located on the internal or external side of the primary position transducers 18 and 19. Let it be in the initial state shown in Fig. 5 (Fig. 6, Fig. 7, Fig. 8), the minimum (maximum, maximum, minimum) mutual inductance of the first 18 and second 19 primary position transducers, since it is non-magnetic (magnetically conductive, mag the conductive, non-magnetic conductive) portion of the inductor 17 is located in the area of the primary transducers 18 and 19. This leads to the fact that the first information output 3 of the secondary transducer V1 <0 (V1 <0, V1 <0, V1 <0) and the second information output 4 secondary converters V2 <0 (V2 <0, V2 <0, V2 <0). When moving the inductor 17 in Fig. 5 to the left (in Fig. 6 to the right, in Fig. 7 to the right, in Fig. 8 to the left), a magnetically conducting (non-magnetic, non-magnetic, magnetic) section of the inductor 17 is brought into the zone of the primary transducer 18, the mutual inductance of the primary transducer 18 increases (decreases, decreases, increases), while the state of the primary converter 19 does not change, which means that the value and polarity of V1 and V2 change, i.e. at the first information output 3 of the secondary converter V1> 0 (V1 <0, V1 <0, V1> 0) and at the second information output 4 of the secondary converter V2 <0 (V2> 0, V2> 0, V2 <0). When moving the inductor 17 in Fig. 5 to the right (in Fig. 6 left, in Fig. 7 left, in Fig. 8 right), a magnetically conducting (non-magnetic, non-magnetic, magnetic) section of the inductor 17 is brought into the zone of the primary transducer 19, the mutual inductance of the primary transducer 19 increases (decreases, decreases, increases), while the state of the primary transducer 18 does not change, which means that the value and polarity of V1 and V2 change, i.e. at the first information output 3 of the secondary converter V1 <0 (V1> 0, V1> 0, V1 <0) and at the second information output 4 of the secondary converter V2> 0 (V2 <0, V2 <0, V2> 0).

The secondary Converter in figure 1 with according to the included secondary windings of the block of primary converters in figure 3 works as follows.

When a harmonic or pulse signal is supplied from the output of source 5 to a positive half-cycle, the current flows through the circuits: the first - the first terminal of the source 5, the primary winding 20 of the first 18 primary position transmitter, the common bus 10, the second terminal of the source 5; the second is the first clamp of the source 5, the primary winding 22 of the second 19 primary position transmitter, the common bus 10, the second clamp of the source 5; the third is the first terminal of the secondary winding 21 of the first 18 primary position transducer, diode 6, element 15, a resistor 11 and a capacitor 12 connected in parallel, a common bus 10, the second terminal of the secondary winding 21 of the first 18 primary position transducer; the fourth is the first terminal of the secondary winding 23 of the second 19 primary position transmitter, the common bus 10, the resistor 11 and the capacitor 12 connected in parallel, the diode 13, the second terminal of the secondary winding 23 of the second 19 primary position converter; fifth - the first terminal of the secondary winding 21 of the first 18 primary position transmitter, diode 6, element 15, diode 13, the second terminal of the secondary winding 23 of the second 19 primary position transmitter, the first terminal of the secondary winding 23 of the second 19 primary position transmitter, the second terminal of the secondary winding 21 of the first 18 primary position transmitter. In the negative half-cycle, the current flows through the following circuits: the first - the second terminal of the source 5, the common bus 10, the primary winding 20 of the first 18 primary position transmitter, the first terminal of the source 5; the second is the second clamp of the source 5, the common bus 10, the primary winding 22 of the second 19 primary position transmitter, the first clamp of the source 5; the third is the second terminal of the secondary winding 21 of the first 18 primary position transducer, a common bus 10, a resistor 8 and a capacitor 9 connected in parallel, a diode 7, the first terminal of the secondary winding 21 of the first 18 primary position transducer; the fourth is the second terminal of the secondary winding 23 of the second 19 primary position transducer, diode 14, element 16, a resistor 8 and a capacitor 9 connected in parallel, a common bus 10, the first terminal of the secondary winding 23 of the second 19 primary position transducer; fifth - the second terminal of the secondary winding 23 of the second 19 primary position transducer, diode 14, element 16, diode 7, the first terminal of the secondary winding 21 of the first 18 primary position transducer, the second terminal of the secondary winding 21 of the first 18 primary position transducer, the first terminal of the secondary winding 23 of the second 19 primary position transmitter. On the capacitors 12 and 9, respectively, voltages V1, V2 are formed with respect to the common bus 10. The value and polarity of these voltages depend on the position of the magnetically conducting section of the inductor 17 located on the inside or outside of the primary position transducers 18 and 19. Let it be in the initial state, as it shown in Fig. 5 (Fig. 6, Fig. 7, Fig. 8), the minimum (maximum, maximum, minimum) mutual inductances of the first 18 and second 19 primary position transducers, since non-magnetic (magnetic, mag the conductive, non-magnetic conductive) portion of the inductor 17 is located in the area of the primary transducers 18 and 19. This leads to the fact that the first information output 3 of the secondary transducer V1 <0 (V1 <0, V1 <0, V1 <0) and the second information output 4 secondary converters V2 <0 (V2 <0, V2 <0, V2 <0). When moving the inductor 17 in Fig. 5 to the left (in Fig. 6 to the right, in Fig. 7 to the right, in Fig. 8 to the left), a magnetically conducting (non-magnetic, non-magnetic, magnetic) section of the inductor 19 is brought into the zone of the primary transducer 18, the mutual inductance of the primary transducer 18 increases (decreases, decreases, increases), while the state of the primary converter 19 does not change, which means that the value and polarity of V1 and V2 change, i.e. at the first information output 3 of the secondary converter V1> 0 (V1 <0, V1 <0, V1> 0) and at the second information output 4 of the secondary converter V2 <0 (V2> 0, V2> 0, V2 <0). When moving the inductor 17 in Fig. 5 to the right (in Fig. 6 left, in Fig. 7 left, in Fig. 8 right), a magnetically conductive (non-magnetic, non-magnetic, magnetically conductive) section of the inductor 17 is brought into the area of the primary transducer 19, inductive coupling in the primary the transducer 19 increases (decreases, decreases, increases), while the state of the primary transducer 18 does not change, which means that the value and polarity of V1 and V2 change, i.e. at the first information output 3 of the secondary converter V1 <0 (V1> 0, V1> 0, V1 <0) and at the second information output 4 of the secondary converter V2> 0 (V2 <0, V2 <0, V2> 0).

The secondary Converter in figure 1 with counterclockwise secondary windings of the block of primary converters in figure 4 works as follows.

When a harmonic or pulse signal is supplied from the output of source 5 to a positive half-cycle, the current flows through the circuits: the first - the first terminal of the source 5, the primary winding 20 of the first 18 primary position transducer, the primary winding 22 of the second 19 primary position transducer, common bus 10, the second source clamp 5; the second is the first terminal of the secondary winding 21 of the first 18 primary position transducer, diode 6, element 15, a resistor 11 and a capacitor 12 connected in parallel, a common bus 10, the second terminal of the secondary winding 21 of the first 18 primary position transducer; the third is the first terminal of the secondary winding 23 of the second 19 primary position transducer, diode 14, element 16, a resistor 8 and a capacitor 9 connected in parallel, a common bus 10, the second terminal of the secondary winding 23 of the second 19 primary position transducer. In the negative half-cycle, the current flows through the following circuits: the first - the second terminal of the source 5, the common bus 10, the primary winding 22 of the second 19 primary position transducer, the primary winding 20 of the first 18 primary position transducer, the first terminal of the source 5; the second is the second terminal of the secondary winding 21 of the first 18 primary position transmitter, a common bus 10, parallel connected resistor 8 and capacitor 9, diode 7, the first terminal of the secondary winding 21 of the first 18 primary position transmitter; the third is the second terminal of the secondary winding 23 of the second 19 primary position transmitter, the common bus 10, the resistor 11 and the capacitor 12 connected in parallel, the diode 13, the first terminal of the secondary winding 23 of the second 19 primary position converter. On the capacitors 12 and 9, respectively, voltages V1 and V2 are formed relative to the common bus 10. The value and polarity of these voltages depend on the position of the magnetically conductive section of the inductor 17 located on the inside or outside of the primary transducers of position 18 and 19. Let it be in the initial state, like this shown in Fig. 5 (Fig. 6, Fig. 7, Fig. 8), the minimum (maximum, maximum, minimum) mutual inductances of the first 18 and second 19 primary position transducers, since non-magnetic (magnetic, ma nitro-conductive, non-magnetically conductive) section of the inductor 17 is located in the area of the primary transducers 18 and 19. This leads to the fact that the first information output 3 of the secondary transducer V1 <0 (V1 <0, V1 <0, V1 <0) and the second information output 4 secondary converters V2 <0 (V2 <0, V2 <0, V2 <0). When moving the inductor 17 in Fig. 5 to the left (in Fig. 6 to the right, in Fig. 7 to the right, in Fig. 8 to the left), a magnetically conducting (non-magnetic, non-magnetic, magnetic) section of the inductor 17 is brought into the zone of the primary transducer 18, the mutual inductance of the primary transducer 18 increases (decreases, decreases, increases), while the state of the primary converter 19 does not change, which means that the value and polarity of V1 and V2 change, i.e. on the first 3 information output of the secondary converter V1> 0 (V1 <0, V1 <0, V1> 0) and on the second 4 information output of the secondary converter V2 <0 (V2> 0, V2> 0, V2 <0). When moving the inductor 17 in Fig. 5 to the right (in Fig. 6 left, in Fig. 7 left, in Fig. 8 right), a magnetically conductive (non-magnetic, non-magnetic, magnetically conductive) section of the inductor 17 is brought into the area of the primary transducer 19, inductive coupling in the primary the transducer 19 increases (decreases, decreases, increases), while the state of the primary transducer 18 does not change, which means that the value and polarity of V1 and V2 change, i.e. on the first 3 information output of the secondary converter V1 <0 (V1> 0, V1> 0, V1 <0) and on the second 4 information output of the secondary converter V2> 0 (V2 <0, V2 <0, V2> 0).

The secondary Converter in figure 1 with the consonant inclusion of the secondary windings of the block of primary converters in figure 4 works as follows.

When a harmonic or pulse signal is supplied from the output of source 5 to a positive half-cycle, the current flows through the circuits: the first - the first terminal of the source 5, the primary winding 20 of the first 18 primary position transducer, the primary winding 22 of the second 19 primary position transducer, common bus 10, the second source clamp 5; the second is the first terminal of the secondary winding 21 of the first 18 primary position transducer, diode 6, element 15, a resistor 11 and a capacitor 12 connected in parallel, a common bus 10, the second terminal of the secondary winding 21 of the first 18 primary position transducer; the third is the first terminal of the secondary winding 23 of the second 19 primary position transmitter, the common bus 10, the resistor 11 and the capacitor 12 connected in parallel, the diode 13, the second terminal of the secondary winding 23 of the second 19 primary position converter; the fourth is the first terminal of the secondary winding 21 of the first 18 primary position transmitter, diode 6, element 15, diode 13, the second terminal of the secondary winding 23 of the second 19 primary position transmitter, the first terminal of the secondary winding 23 of the second 19 primary position transmitter, the second terminal of the secondary winding 21 of the first 18 primary position transmitter. In the negative half-cycle, the current flows through the following circuits: the first - the second terminal of the source 5, the common bus 10, the primary winding 22 of the second 19 primary position transducer, the primary winding 20 of the first 18 primary position transducer, the first terminal of the source 5; the second is the second terminal of the secondary winding 21 of the first 18 primary position transmitter, a common bus 10, parallel connected resistor 8 and capacitor 9, diode 7, the first terminal of the secondary winding 21 of the first 18 primary position transmitter; the third is the second terminal of the secondary winding 23 of the second 19 primary position transducer, diode 14, element 16, a resistor 8 and capacitor 9 connected in parallel, a common bus 10, the first terminal of the secondary winding 23 of the second 19 primary position transducer; the fourth is the second terminal of the secondary winding 23 of the second 19 primary position transmitter, diode 14, element 16, diode 7, the first terminal of the secondary winding 21 of the first 18 primary position transmitter, the second terminal of the secondary winding 21 of the first 18 primary position transmitter, the first terminal of the secondary winding 23 of the second 19 primary position transmitter. On the capacitors 12 and 9, respectively, voltages V1 and V2 are generated relative to the common bus 10. The value and polarity of these voltages depend on the position of the magnetically conductive portion of the inductor 17 located on the inside or outside of the primary position transducers 18 and 19. Let it be in the initial state, as it is shown in Fig.5 (Fig.6, Fig.7, Fig.8), the minimum (maximum, maximum, minimum) inductive coupling between the primary and secondary windings of the first 18 and second 19 primary position transducers, since the non-magnet the conductive (magnetically conductive, magnetically conductive, non-magnetically conductive) portion of the inductor 17 is located in the area of the primary transducers 18 and 19. This leads to the fact that at the first 3 information output of the secondary transducer V1 <0 (V1 <0, V1 <0, V1 <0) and on the second 4 information output of the secondary Converter V2 <0 (V2 <0, V2 <0, V2 <0). When the inductor 17 is moved in Fig. 5 to the left (in Fig. 6 to the right, in Fig. 7 to the right, in Fig. 8 to the left), a magnetically conducting (non-magnetic, non-magnetic, magnetically conducting) section of the inductor 17 is brought into the primary transducer zone 18, inductive coupling in the primary the transducer 18 increases (decreases, decreases, increases), while the state of the primary transducer 19 does not change, which means that the value and polarity of V1 and V2 change, i.e. on the first 3 information output of the secondary converter V1> 0 (V1 <0, V1 <0, V1> 0) and on the second 4 information output of the secondary converter V2 <0 (V2> 0, V2> 0, V2 <0). When moving the inductor 17 in Fig. 5 to the right (in Fig. 6 left, in Fig. 7 left, in Fig. 8 right), a magnetically conductive (non-magnetic, non-magnetic, magnetically conductive) section of the inductor 17 is brought into the area of the primary transducer 19, inductive coupling in the primary the transducer 19 increases (decreases, decreases, increases), while the state of the primary transducer 18 does not change, which means that the value and polarity of V1 and V2 change, i.e. on the first informational 3 output of the secondary converter V1 <0 (V1> 0, V1> 0, V1 <0) and on the second informational 4 output of the secondary converter V2> 0 (V2 <0, V2 <0, V2> 0).

The secondary Converter in figure 11 with the block of primary sensors in figure 2 works as follows.

When a time-varying signal is supplied from the output of source 5 to a positive half-cycle, current flows through the following circuits: the first - the first terminal of source 5, the winding 18 of the first primary position transmitter, diode 6, element 15, resistor 11, common bus 10, and the second terminal of source 5 ; the second is the first clamp of the source 5, the winding 18 of the first primary position transmitter, diode 6, the capacitor 12, the common bus 10, the second clamp of the source 5; the third is the first clamp of the source 5, the winding 19 of the first primary position transducer, diode 14, element 16, the resistor 8, the common bus 10, the second clamp of the source 5; the fourth is the first terminal of the source 5, the winding 19 of the first primary position transmitter, diode 14, the capacitor 9, the common bus 10, the second terminal of the source 5. In the negative half-cycle, the current flows through the following circuits: the first is the second terminal of the source 5, the common bus 10, the resistor 11, diode 13, winding 19 of the second primary position transmitter, the first clamp of the source 5; the second is the second clamp of the source 5, the common bus 10, the capacitor 12, the element 15, the diode 13, the winding 19 of the second primary position transmitter, the first clamp of the source 5; the third is the second terminal of the source 5, the common bus 10, the resistor 8, the diode 7, the winding 18 of the first primary position transmitter, the first terminal of the source 5; the fourth is the second terminal of the source 5, the common bus 10, the capacitor 9, the element 16, the diode 7, the winding 18 of the first primary position transmitter, the first terminal of the source 5. On the capacitors 12 and 9, respectively, voltages V1, V2 are generated relative to the common bus 10. The value and the polarity of these voltages depends on the position of the magnetically conductive portion of the inductor 17 located on the inner or outer side of the primary position transducers 18 and 19. Let it be in the initial state, as shown in Fig. 5 (Fig. 6, Fig. 7, Fig. 8) integrated resistance The primary position transducer 18 is approximately equal to the complex resistance of the primary position transducer 19, since the non-magnetic (magnetically conductive, magnetically conductive, non-magnetic) portion of the inductor 17 is located in the area of the primary transducers 18 and 19. This leads to the fact that the first information output 3 of the secondary transducer V1 > 0 (V1 <0, V1 <0, V1> 0) and on the second information output 4 of the secondary converter V2> 0 (V2 <0, V2 <0, V2> 0). When moving the inductor 17 in Fig. 5 to the left (in Fig. 6 to the right, in Fig. 7 to the right, in Fig. 8 to the left), a magnetically conducting (non-magnetic, non-magnetic, magnetic) section of the inductor 17, the complex resistance of the primary converter 18 sharply increases (decreases, decreases, increases), while the complex resistance of the primary converter 19 does not change, which means that the value and polarity of V1 and V2 change, i.e. at the first information output 3 of the secondary converter V1 <0 (V1> 0, V1> 0, V1 <0) and at the second information output 4 of the secondary converter V2> 0 (V2 <0, V2 <0, V2> 0). When moving the inductor 17 in Fig. 5 to the right (in Fig. 6 left, in Fig. 7 left, in Fig. 8 right), a magnetically conducting (non-magnetic, non-magnetic, magnetic) section of the inductor 17, the complex resistance of the primary converter 19 sharply increases (decreases, decreases, increases), while the complex resistance of the primary transducer 18 does not change, which means that the value and polarity of V1 and V2 change, i.e. at the first information output 3 of the secondary converter V1> 0 (V1 <0, V1 <0, V1> 0) and at the second information output 4 of the secondary converter V2 <0 (V2> 0, V2> 0, V2 <0).

All variants of the block of primary converters for the basic circuit of the secondary converter in figure 1 are connected to the similar conclusions for the basic circuit of the secondary converter in figure 11.

For all variants of the execution of the block of primary position transducers in this sensor, there is a relationship of channels when a change in the complex resistance of one of the primary transducers affects the voltage values from the outputs of the secondary transducer. This effect is enhanced if a current source is used as a source of a time-variable signal. Moreover, in this converter, the signs of the output voltages, which are an informative parameter, are not changed.

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

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

- for the claimed invention in the form described in the independent claims, the possibility of its implementation using the methods and methods described above or known prior to the priority date has been confirmed;

- a tool embodying the claimed invention in its implementation, is able to achieve a positive technical result.

Therefore, the claimed invention meets the requirement of "industrial applicability".

Information sources

1. US patent No. 3688190, NKl 324 / 61R, MKL G 01 R 27/26, August 29, 1972.

2. US patent No. 3883812, Ncl 329/166, MKL H 03 D 1/10, May 13, 1975.

Claims (16)

1. A sensor for three-position control of the position, containing a unit consisting of two independent inductive (transformer) primary position transducers, the complex resistance (mutual inductance) of which changes when the controlled object is moved, and a secondary converter, the first and second outputs of which are connected respectively to the first and the second inputs of the block of primary converters, the first and second outputs of which are connected respectively to the first and second inputs of the secondary converter For having a first and second information outputs and containing a source of a time-variable signal, for example, harmonic or pulsed, the first and second terminals of which are connected to the first and second outputs of the secondary converter, respectively, whose first input is connected to the anode (cathode) of the first diode and the cathode ( anode) of the second diode, the anode (cathode) of which is connected to the first output of the second resistor, to the second information output of the secondary converter and to the first output of the second capacitor, the second output to is connected to the second output of the second resistor, with the second output of the secondary converter, a common bus, the second output of the first resistor and the second output of the first capacitor, the first output of which is connected to the first output of the first resistor, to the first information output of the secondary converter and to the anode (cathode) the third diode, the cathode (anode) of which is connected to the second input of the secondary converter and the anode (cathode) of the fourth diode, characterized in that two reference elements are introduced, the first and second conclusions of th exemplary element are respectively connected to the cathode (anode) of said first diode and to the anode (cathode) of the third diode, the first and second terminals of the second model element are respectively connected to the cathode (anode) of the fourth diode and the anode (cathode) of said second diode. 2. The sensor according to claim 1, characterized in that the first and second exemplary element are resistors (inductances). 3. The sensor according to claim 1, characterized in that the first and second exemplary element, respectively, are a resistor (inductance) and inductance (resistor). 4. The sensor according to claim 1, characterized in that the unit contains two independent inductive primary position transducers, the first conclusions of which are connected to the first input of the block, the second outputs of the first and second independent inductive primary position transducers, respectively, are connected to the first and second outputs of it. 5. The sensor according to claim 1, characterized in that the unit contains two independent transformer primary position transducers, each of which contains primary and secondary windings, and the beginnings (ends) of the primary windings of the first and second independent transformer primary position transducers are connected to the second input of the block primary position transducers, the first input of which is connected to the ends (beginnings) of the primary windings of the first and second independent primary position transducers, the beginning (end) of the secondary the windings of the first primary position transducer is connected to the first output of the block of primary position transducers, the second output of which is connected to the beginning (end) of the secondary winding of the second independent primary position transmitter, the end (beginning) of which secondary winding is connected to the end (beginning) of the secondary winding of the first primary position transducer and the second input of the block of independent primary position transducers. 6. The sensor according to claim 1, characterized in that the unit contains two independent transformer primary position transducers, each of which contains a primary and secondary windings, the beginning (end) of the primary winding of the first and the beginning (end) of the primary winding of the second independent transformer primary transducers positions are connected to the second input of the block of primary position transducers, the first input of which is connected to the end (beginning) of the primary winding of the first and the end (beginning) of the primary winding of the second are independent primary position transducers, the end (beginning) of the secondary winding of the first primary position transducer is connected to the first output of the block of primary position transducers, the second output of which is connected to the beginning (end) of the secondary winding of the second independent primary position transducer, the end (beginning) of the secondary winding of which is connected to the beginning (end) of the secondary winding of the first primary position transducer and the second input of the block of independent primary position transducers. 7. The sensor according to claim 1, characterized in that the unit contains two independent transformer primary position transducers, each of which contains a primary and secondary windings, the beginning (end) of the primary winding of the first and the end (beginning) of the primary winding of the second independent transformer primary transducers positions are interconnected, the end (beginning) of the primary winding of the first and the beginning (end) of the primary winding of the second independent transformer primary position transducers are connected respectively to the first and second inputs of the block of primary position transducers, to the first and second outputs of which respectively are connected the beginning (end) of the secondary winding of the first and the beginning (end) of the second winding of the second independent transformer primary position transducers, in which the ends (beginnings) of the secondary windings are connected to the second input block primary position transducers. 8. The sensor according to claim 1, characterized in that the unit contains two independent transformer primary position transducers, each of which contains a primary and secondary winding, the beginning (end) of the primary winding of the first and the end (beginning) of the primary winding of the second independent transformer primary transducers positions are interconnected, the end (beginning) of the primary winding of the first and the beginning (end) of the primary winding of the second independent transformer primary position transducers are connected respectively to the first and second inputs of the block of primary position transducers, to the first and second outputs of which respectively are connected the end (beginning) of the secondary winding of the first and the beginning (end) of the second winding of the second independent transformer primary position transducers, which respectively have a beginning (end) and end (beginning) secondary windings are connected to the second input of the block of primary position transducers. 9. A sensor for three-position control of the position, containing a block consisting of two independent inductive (transformer) primary position transducers, the complex resistance (mutual inductance) of which changes when the controlled object is moved, and a secondary converter, the first and second outputs of which are connected respectively to the first and the second inputs of the block of primary converters, the first and second outputs of which are connected respectively to the first and second inputs of the secondary converter For having a first and second information outputs and containing a source of a time-variable signal, for example, harmonic or pulsed, the first and second terminals of which are connected to the first and second outputs of the secondary converter, respectively, the first input of which is connected to the anode (cathode) of the first diode and the cathode ( anode) of the second diode, the anode (cathode) of which is connected to the first terminal of the second resistor, the second information output of the secondary converter is connected to the first terminal of the second capacitor, the second the water of which is connected to the second terminal of the second resistor, to the second output of the secondary converter, to the common bus, to the second terminal of the first resistor and to the second terminal of the first capacitor, the first terminal of which is connected to the first information output of the secondary converter and the cathode (anode) of the first diode, the first the output of the first resistor is connected to the anode (cathode) of the third diode, the cathode (anode) of which is connected to the second input of the secondary converter and the anode (cathode) of the fourth diode, the cathode (anode) of which is connected to the second output of the second capacitor, characterized in that two reference elements are introduced, the first and second conclusions of the first reference element are connected respectively to the cathode (anode) of the first diode and to the anode (cathode) of the third diode, the first and second conclusions of the second reference element are connected respectively to the cathode (anode) of the fourth diode and to the anode (cathode) of the second diode. 10. The sensor according to claim 9, characterized in that the first and second exemplary element are resistors (inductances). 11. The sensor according to claim 9, characterized in that the first and second exemplary element, respectively, are a resistor (inductance) and inductance (resistor). 12. The sensor according to claim 9, characterized in that the unit contains two independent inductive primary position transducers, the first conclusions of which are connected to the first input of the block, the second outputs of the first and second independent inductive primary position transducers, respectively, are connected to the first and second outputs of it. 13. The sensor according to claim 9, characterized in that the unit contains two independent transformer primary position transducers, each of which contains primary and secondary windings, and the beginnings (ends) of the primary windings of the first and second independent transformer primary position transducers are connected to the second input of the block primary position transducers, the first input of which is connected to the ends (beginnings) of the primary windings of the first and second independent primary position transducers, the beginning (end) of the secondary the windings of the first primary position transducer is connected to the first output of the block of primary position transducers, the second output of which is connected to the beginning (end) of the secondary winding of the second independent primary position transducer, the end (beginning) of which secondary windings is connected to the end (beginning) of the secondary winding of the first primary position transducer and the second input of the block of independent primary position transducers. 14. The sensor according to claim 9, characterized in that the unit contains two independent transformer primary position transducers, each of which contains a primary and secondary winding, the beginning (end) of the primary winding of the first and the beginning (end) of the primary winding of the second independent transformer primary transducers positions are connected to the second input of the block of primary position transducers, the first input of which is connected to the end (beginning) of the primary winding of the first and the end (beginning) of the primary winding of the second are independent x primary position transducers, the end (beginning) of the secondary winding of the first primary position transducer is connected to the first output of the block of primary position transducers, the second output of which is connected to the beginning (end) of the secondary winding of the second independent primary position transducer, the end (beginning) of the secondary winding of which is connected to the beginning (end) of the secondary winding of the first primary position transducer and the second input of the block of independent primary position transducers. 15. The sensor according to claim 9, characterized in that the unit contains two independent transformer primary position transducers, each of which contains a primary and secondary windings, the beginning (end) of the primary winding of the first and the end (beginning) of the primary winding of the second independent transformer primary transducers positions are interconnected, the end (beginning) of the primary winding of the first and the beginning (end) of the primary winding of the second independent transformer primary position transducers are connected respectively the first and second inputs of the block of primary position transducers, to the first and second outputs of which respectively are connected the beginning (end) of the secondary winding of the first and the beginning (end) of the secondary winding of the second independent transformer primary position transducers, in which the ends (beginnings) of the secondary windings are connected to the second input block of primary position transducers. 16. The sensor according to claim 9, characterized in that the unit contains two independent transformer primary position transducers, each of which contains a primary and secondary windings, the beginning (end) of the primary winding of the first and the end (beginning) of the primary winding of the second independent transformer primary transducers positions are interconnected, the end (beginning) of the primary winding of the first and the beginning (end) of the primary winding of the second independent transformer primary position transducers are connected respectively the first and second inputs of the block of primary position transducers, to the first and second outputs of which respectively are connected the end (beginning) of the secondary winding of the first and the beginning (end) of the second winding of the second independent transformer primary position transducers, which respectively have a beginning (end) and end (beginning) secondary windings are connected to the second input of the block of primary position transducers.

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