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Transducer for controlling position in three-step mode
Transducer for controlling position in three-step mode
IPC classes for russian patent Transducer for controlling position in three-step mode (RU 2288478):
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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

 

The invention relates to measurement technology and is designed for receiving digital information about the three-position the position of the controlled object by converting modules complex resistance or mutual inductance parametric transducers position in the active signal.

A known sensor for measuring the movement of containing block, consisting of two independent inductive (transformer) primary measuring transducers, impedance (mutual inductance) which varies with the movement of the controlled object, and the secondary measuring Converter, the first and second outputs of which are connected respectively with the first and second inputs of the block primary measuring converters, the first and second outputs of which are connected respectively to first and second inputs of the secondary measuring Converter having first and second information outputs and containing a source of time-varying signal, such as harmonic or pulse, the first and second terminals which are connected to the first and the second outputs of the secondary measuring Converter, respectively, the first input connected to the anode (cathode) of the first diode and the cathode (anode) of the second diode, the anode (cathode) which the treatment tip can is coupled to a common bus, to the second terminal of the source, to the first conclusions of the first and second resistors, the first conclusions of the first and second capacitors and to the anode (cathode) of the third diode, the cathode (anode) which is connected to a second input of the secondary measuring Converter and anode (cathode) of the fourth diode, the cathode (anode) of the first diode is connected to the first information output secondary measuring Converter with the second pins of the first resistor and a capacitor, the cathode (anode) of the fourth diode is connected with the second information output secondary measuring Converter with the second pins of the second resistor and capacitor [1].

A disadvantage of the known device, when used as a position sensor, is the dependence of the conversion into an electrical signal values and change the value of the complex impedance of the first (second) of two inductive transducers move or position change of the impedance of the second (first) primary transformer moving coil.

A known sensor for measuring the movement of containing block, consisting of two independent inductive (transformer) primary measuring transducers, impedance (mutual inductance) which varies with the pen is the displacement of the controlled object, and secondary measuring Converter, the first and second outputs of which are connected respectively with the first and second inputs of the block primary measuring converters, the first and second outputs of which are connected respectively to first and second inputs of the secondary measuring Converter having first and second information outputs and containing a source of time-varying signal, such as harmonic or pulse, the first and second terminals of which are connected to first and second outputs of the secondary measuring Converter, respectively, the first input connected to the anode (cathode) of the first diode and the cathode (anode) of the second diode, the anode (cathode) which is connected to the second the information output of the secondary measuring Converter and the first output of the second capacitor, the second terminal of which is connected to a common bus, a second clamp source and the second output of the first capacitor, a first output which is connected to the first information output secondary measuring Converter and anode (cathode) of the third diode, the cathode (anode) which is connected to the second input of the secondary measuring Converter and anode (cathode) of the fourth diode, the cathode (anode) of the first and fourth diodes are connected respectively to the anodes (or cathodes) of tert is it and second diodes [2].

A disadvantage of the known device, when used as a position sensor, is the dependence of the conversion into an electrical signal values and change the value of the complex impedance of the first (second) of two inductive transducers move or position change of the impedance of the second (first) primary transformer moving coil.

The basis for this invention is the problem of obtaining digital information about the three-position the position of the controlled object by using two independent transducers provisions.

This goal is achieved by the fact that the sensor for three-position control position containing block, consisting of two independent inductive (transformer) primary converters provisions impedance (mutual inductance) which varies with the movement of the controlled object, and the secondary Converter, the first and second outputs of which are connected respectively with the first and second inputs of unit transducers, the first and second outputs of which are connected respectively to first and second inputs of the secondary Converter having first and second information outputs and containing the AC in the straps of the signal, for example, harmonic or pulse, the first and second terminals of which are connected to first and second outputs of the secondary Converter, respectively, the first input connected to the anode (cathode) of the first diode and the cathode (anode) of the second diode, the anode (cathode) which is connected to the first output of the second resistor, to the second information output of the secondary of the Converter and to the first output of the second capacitor, the second terminal of which is connected with the second output of the second resistor, with the second output of the secondary Converter, a shared bus, a second output of the first resistor and the second output of the first capacitor, a first output which is connected to the first output the first resistor to the first information output of the secondary of the Converter and to the anode (cathode) of the third diode, the cathode (anode) which is connected to the second input of the secondary Converter and anode (cathode) of the fourth diode, the introduction of two exemplary element, the first and second findings of the first model element connected respectively to the cathode (the anode of the first diode and to the anode (cathode) of the third diode, the first and second findings of the second exemplary element connected respectively to the cathode (the anode) of the fourth diode and to the anode (cathode) of the second diode.

In this device the proposed execution of two model elements, so PE is the first and the second exemplary element are resistors (inductance).

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

When different versions of model elements, each of them is receiving the reference voltage for the opposite, against his shoulder secondary of the Converter.

In this device the proposed execution of a block of transducers position so that the unit contains two independent inductive transducers position, the first conclusions of which is connected to the first input unit, to the first and second outputs of which are connected respectively to the second, the findings of the first and second independent inductive transducers provisions.

In this device the proposed execution of a block of transducers position so that the unit contains two independent transformer primary transducer position, each of which contains a primary and secondary winding, and the beginning (end) of the primary windings of the first and second independent transformer transducers position connected to the second input of unit transducers position, the first input connected to the ends (the basis) is ervicing windings of the first and second independent transducers provisions beginning (end) of the secondary winding of the first primary Converter provisions connected to the first output unit transducers position, 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 end (beginning) of the secondary winding of the first primary transducer position and the second input unit independent transducers provisions.

Additionally, this unit of the proposed execution of a block of transducers position so that the unit contains two independent transformer primary transducer position, each of which contains a primary and secondary winding, and the beginning (end) of the primary winding of the first and the beginning (end) of the primary winding of the second independent transformer transducers position connected to the second input of unit transducers position, the first input connected to the end (beginning) of the primary winding of the first and the end (beginning) of the primary winding of the second independent transducers position, the end (beginning) of the secondary winding of the first primary Converter provisions connected to the first output unit transducers position, 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 transducer position and the second input unit independent transducers provisions.

Additionally, this unit of the proposed execution of a block of transducers position so that the unit contains two independent transformer primary transducer position, each of which contains a primary and secondary winding, and the beginning (end) of the primary winding of the first and the end (beginning) of the primary winding of the second independent transformer transducers provisions 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 transducers provisions connected respectively to first and second inputs of unit transducers position, the first and second outputs of which are respectively connected to the beginning (end) the secondary winding of the first and the beginning (end) of the secondary winding of the second independent transformer transducers position in which the end (beginning) of the secondary winding is connected to the second input transducers provisions.

Additionally, this device proposed execution unit pervi the data converters provisions so the unit contains two independent transformer primary transducer position, each of which contains a primary and secondary winding, and the beginning (end) of the primary winding of the first and the end (beginning) of the primary winding of the second independent transformer primary transducer position 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 transducer position connected respectively to first and second inputs of unit transducers position, the first and second outputs of which are respectively connected to the end (beginning) of the secondary winding of the first and the beginning (end) of the secondary winding of the second independent transformer transducers position, in which the beginning (end) and the end (beginning) of the secondary winding is connected to the second input transducers provisions.

In different designs two independent inductive or transformer primary transducer position through the inductor associated with the controlled object to provide in conjunction with the proposed secondary Converter receiving information about the three provisions of the controlled object.

This goal is achieved by the fact that mo is in the sensor for three-position control position, containing block, consisting of two independent inductive (transformer) primary converters provisions impedance (mutual inductance) which varies with the movement of the controlled object, and the secondary Converter, the first and second outputs of which are connected respectively with the first and second inputs of unit transducers, the first and second outputs of which are connected respectively to first and second inputs of the secondary Converter, which contains a source of time-varying signal, such as harmonic or pulse, the first and second terminals of which are connected to first and second outputs of the secondary Converter, respectively, the first input connected to the anode (cathode) the first diode and the cathode (anode) of the second diode, the anode (cathode) which is connected to the first output of the second resistor, the second information output of the secondary of the Converter is connected to the first output of the second capacitor, the second terminal of which is connected to the second output of the second resistor to the second output of the secondary of the Converter to a common bus, to the second output of the first resistor and to the second output of the first capacitor, a first output which is connected to the first information output of the secondary of the transformer and the cathode (the anode) first what about the diode, the first output of the first resistor is connected to anode (cathode) of the third diode, the cathode (anode) which is connected to the second input of the secondary Converter and anode (cathode) of the fourth diode, the cathode (anode) which is connected to the first output of the second capacitor, the introduction of two exemplary element, the first and second findings of the first model element connected respectively to the cathode (the anode of the first diode and to the anode (cathode) of the third diode, the first and second findings of the second exemplary element connected respectively to the cathode (the anode) of the fourth diode and to the anode (cathode) of the second diode.

In this device the proposed execution of two model elements so that the first and second exemplary element are resistors (inductance).

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

When different versions of model elements, each of them is receiving the reference voltage for the opposite, against his shoulder secondary of the Converter.

In this device the proposed execution of a block of transducers position so that the unit contains two independent primary inductive convert what the user position, the first conclusions of which is connected to the first input unit, to the first and second outputs of which are connected respectively to the second, the findings of the first and second independent inductive transducers provisions.

In this device the proposed execution of a block of transducers position so that the unit contains two independent transformer primary transducer position, each of which contains a primary and secondary winding, and the beginning (end) of the primary windings of the first and second independent transformer transducers position connected to the second input of unit transducers position, the first input connected to the ends (the basis) of the primary windings of the first and second independent transducers provisions, beginning (end) of the secondary winding of the first primary Converter provisions connected to the first output unit transducers position, the second output of which is connected to the beginning (end secondary winding of the second independent primary transducer position, the end (beginning) of the secondary winding of which is connected to the end (beginning) of the secondary winding of the first primary transducer position and the second input unit independent transducers provisions.

Complement is Ino in this unit of the proposed execution of a block of transducers position so the unit contains two independent transformer primary transducer position, each of which contains a primary and secondary winding, and the beginning (end) of the primary winding of the first and the beginning (end) of the primary winding of the second independent transformer transducers position connected to the second input of unit transducers position, the first input connected to the end (beginning) of the primary winding of the first and the end (beginning) of the primary winding of the second independent transducers position, the end (beginning) of the secondary winding of the first primary Converter provisions connected to the first output unit transducers position, the second output of which is connected with the beginning (by the 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 transducer position and the second input unit independent transducers provisions.

Additionally, this unit of the proposed execution of a block of transducers position so that the unit contains two independent transformer primary transducer position, each of which contains a primary and secondary winding, moreover, the beginning (end) of the primary winding of the first and the end (beginning) of the primary winding of the second independent transformer transducers provisions 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 transducers provisions connected respectively to first and second inputs of unit transducers position, the first and second outputs of which are respectively connected to the beginning (end) of the secondary winding of the first and the beginning (end) of the secondary winding of the second independent transformer transducers position in which the end (beginning) of the secondary winding is connected to the second input transducers provisions.

Additionally, this unit of the proposed execution of a block of transducers position so that the unit contains two independent transformer primary transducer position, each of which contains a primary and secondary winding, and the beginning (end) of the primary winding of the first and the end (beginning) of the primary winding of the second independent transformer primary transducer position 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 transducer position connected respectively to first and second inputs of unit transducers position, the first and second outputs which the CSOs are respectively connected end (the secondary winding of the first and the beginning (end) of the secondary winding of the second independent transformer transducers provisions we are beginning (end) and the end (beginning) of the secondary winding is connected to the second input transducers provisions.

In different designs two independent inductive or transformer primary transducer position through the inductor associated with the controlled object to provide in conjunction with the proposed secondary Converter receiving information about the three provisions of the controlled object.

Conducted by the applicant's analysis of the prior art, including searching by the patent and scientific and technical information sources and identify sources that contain information about the equivalents of the claimed invention, has allowed to establish that at present there is no similar, characterized by signs, identical to all the essential features of the claimed invention, and the definition from the list of identified unique prototype as the most similar set of features analogue has identified a set of essential towards perceived by the applicant to the technical result of the distinctive features in the claimed object set forth in the claims. Therefore, the claimed invention meets the requirement of "novelty".

To verify compliance of the claimed invention-demand izobretatelskikh the level of the applicant conducted an additional search of the known solutions in order to identify signs, match the distinctive features of the prototype of the characteristics of the claimed invention, the results of which show that the claimed invention is not necessary for the expert in the obvious way from the prior art, a particular applicant identified transformation to achieve a technical result provided as the essential features of the claimed invention, in particular the claimed invention as the essential features are provided the following conversions:

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

- replacement of any part of the other known means known part to achieve a technical result, in respect of which it is the effect of such a change;

- the exclusion of any part of the funds while the exclusion of its functions and the achievement of the standard for such a case result;

- increasing the number of identical elements to enhance the technical result due to the presence in the vehicle is of such elements;

- execution of a known drug or part of a known material to achieve those the technical result due to the known properties of the material;

- creation of tools, consisting of well-known parts, the choice of which and the connection between them is made on the basis of known rules, and achievable technical result 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 the sensor for three-position control provisions in the scope of independent claim 1 of the claims. In figure 2, figure 3 and figure 4 reveals some versions of the unit transducers position. Figure 5, 6 (7, Fig) schematically shows options for the location of the Central conductive (Central amagnitude) plot of the inductor (conductive area is shaded), with lesser or greater length "b" compared to the distance "a" between the first and second primary converters provisions. Figure 9 and figure 10 are shown respectively in three zones unambiguous position control. The difference is that while maintaining the length of the inner zone is equal to "+d" (see figure 5, 6, 7, Fig), the length "b" of the side zones figure 10 (which corresponds to 6, Fig) more than figure 9 (which corresponds to figure 5, 7), the value of "C+d". Thus, by varying the distance is receiving "a" between the primary converters, length "b" conductive or amagnitude plot, "a-b=C+d (5, 7) or "b-a=C+d (6, Fig), you can install the necessary three zones of control provisions. Figure 11 shows the sensor for three-position control provisions in the scope of independent claim 9 of the claims.

Information confirming the ability of the invention to provide the above technical result are as follows.

The three-position sensor for controlling the position of figure 1 contains a block 1, consisting of two independent inductive (transformer) primary converters provisions impedance (mutual inductance) which varies with the movement of the controlled object, and the secondary Converter 2, the first and second outputs of which are connected respectively with the first and second inputs of unit 1 primary transducers, the first and second outputs of which are connected respectively to first and second inputs of the secondary Converter 2 having the first 3 and second 4 information outputs and contains the source for the 5 time-varying signal, such as harmonic or pulse, the first and second clamps which is connected to the first and second outputs of the secondary Converter 2, respectively, the first input of which is connected to the anode (cathode) is pout 6 diode and the cathode (the anode) 7 second diode, the anode (cathode) which is connected to the first output of the second resistor 8, 4 information to the second output of the secondary of the Converter 2 and to the first output of the second capacitor 9, the second terminal of which is connected with the second output of the second resistor 8, with the second output of the secondary of the Converter 2, the common bus 10, the second output of the first resistor 11 and the second output of the first capacitor 12, the first output of which is connected to the first output of the first resistor 11, to the first 3 information output of the secondary of the Converter and to the anode (cathode) 13 third diode, the cathode (anode) which is connected to the second input the secondary of the Converter 2 and the anode (cathode) 14 fourth diode, the first and second findings of the first 15 of a model element are connected respectively to the cathode (the anode) of the first 6 diode and to the anode (cathode) 13 third diode, the first and second findings of the second 16 of the reference element are connected respectively to the cathode (anode) 14 fourth diode and to the anode (cathode) 7 second diode.

The unit transducers provisions 1 sensor 2 includes a coil 17 located inside or outside of two independent inductive transducers positions 18 and 19, the first conclusions of which is connected to the first input unit 1, the first and second outputs of which are connected respectively to the second, the findings of the first 18 and is showing 19 independent inductive transducers provisions.

The unit transducers provisions 1 sensor figure 3 contains the inductor 17 located inside or outside of two independent transformer transducers positions 18 and 19, each of which contains the 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 transducers position connected to the first input of the transducers 1, the second input is connected with the second findings of the primary windings 20 and 22 of the first 18 and second 19 independent transducers, the first terminal of the secondary winding 21 of the first 18 of the transducer position connected to the first output unit transducers 1, the second output of which is connected to the first terminal of the secondary winding 23 of the second 19 independent of the transducer, the second terminal of the secondary winding 23 of which is connected with the second terminal of the secondary winding 21 of the first 18 of the transducer position and the second input unit independent transducers provisions 1.

The unit transducers provisions 1 sensor figure 4 contains the inductor 17 located inside or outside of two independent transformer transducers positions 18 and 19, each of which contains PE the primary and secondary winding 20, 21 and 22, 23, and the first output of the primary winding 20 of the first 18 and the second terminal of the primary winding 22 of the second 19 independent transformer transducers provisions are interconnected, the second terminal of the primary winding 20 of the first 18 and the first output of the primary winding 22 of the second 19 independent transformer transducers provisions connected respectively to first and second inputs of unit transducers 1, the first and second outputs of which are respectively connected to the first terminal of the secondary windings 21 and 23 of the first 18 and second 19 independent transformer transducers position in which the second terminal of the secondary windings 21 and 23 are connected with the second input transducers provisions 1.

The three-position sensor for controlling the position of figure 11 contains the block 1, consisting of two independent inductive (transformer) primary converters provisions impedance (mutual inductance) which varies with the movement of the controlled object, and the secondary Converter 2, the first and second outputs of which are connected respectively with the first and second inputs of unit 1 primary transducers, the first and second outputs of which are connected respectively to the first and second secondary inputs into the on of the motor 2, with the first 3 and second 4 information outputs and contains the source for the 5 time-varying signal, such as harmonic or pulse, the first and second terminals of which are connected to first and second outputs of the secondary Converter 2, respectively, the first input of which is connected to the anode (cathode) of the first 6 diode and the cathode (the anode) 7 second diode, the anode (cathode) which is connected to the first output of the second resistor 8, 4 second information output of the secondary of the Converter 2 is connected to the first output of the second capacitor 9, the second terminal of which is connected to the second output of the second resistor 8, to the second the secondary output of the Converter 2, to the common bus 10, to the second output of the first resistor 11 and to the second output of the first capacitor 12, the first output of which is connected to the first 3 information to the secondary output of the Converter 2 and the cathode (the anode) of the first 6 diode, the first output of the first resistor 11 is connected to anode (cathode) 13 third diode, the cathode (anode) which is connected to the second input of the secondary Converter 2 and the anode (cathode) 14 fourth diode, the cathode (anode) which is connected to the first output of the second capacitor 9, the first and second findings of the first 15 exemplary element connected respectively to the cathode (the anode) of the first 6 diode and to the anode (cathode) 13 third diode, the first and the WTO the first findings of the second 16 of the reference element are connected respectively to the cathode (anode) 14 fourth diode and to the anode (cathode) 7 second diode.

The secondary Converter in figure 1 with the unit transducers in figure 2 operates as follows.

When submitting from the output of the source 5 time-varying signal in the positive half-cycle the current flows through the following circuit: - the first clip source 5, the winding 18 of the first primary Converter provisions, the diode 6, the element 15, the parallel connected resistor 11 and the capacitor 12, the common bus 10, the second clip channel 5; the second is the first clip of the source 5, the winding 19 of the first primary Converter provisions, the diode 14, the element 16, the parallel connected resistor 8 and the capacitor 9, the common bus 10, the second clip channel 5. In the negative half-cycle the current flows through the following circuit: first - second clip of the source 5, the common bus 10, the parallel connected resistor 11 and capacitor 12, diode 13, the winding 19 of the first primary Converter position, the first clamp source 5, and the second - second clip of the source 5, the common bus 10, the parallel connected resistor 8 and capacitor 9, diode 7, the winding 18 of the first primary Converter position, the first clamp source 5. The capacitors 12 and 9 respectively are formed voltages V1, V2 relative to a common bus 10. The value and polarity of these voltages depend on the position of the conductive section of the inductor 17 located internal or external to the article the Rhone transducers regulations 18 and 19. Let the initial state, as shown in figure 5 (Fig.6, Fig.7, Fig), impedance of the transducer 18 position is approximately equal to the complex impedance of the transducer 19 of the regulations, as amagnitude (magnetic conductive, magnetic conductive, amagnitude) plot of the inductor 17 is in the area of 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 the second information output 4 of the secondary Converter V2<0 (V2<0, V2<0, V2<0). When moving inductor 17 figure 5 to the left (figure 6 right 7 right on Fig left) in the area of the primary Converter 18 is supplied conductive (amagnitude, amagnitude, conductive) plot of inductor 17, the impedance of the transducer 18 is sharply increases (decreases, increases), whereas the impedance of the transducer 19 is not changed, which means that changes the value and the polarity of VI and V2, i.e. on the first information output 3 of the secondary Converter V1<0 (V1>0, V1>0, V1<0) and the second information output 4 of the secondary Converter V2>0 (V2<0, V2<0, V2>0). When moving inductor 17 figure 5 to the right (figure 6 left, 7 l is Oh, on Fig right) in the area of the primary Converter 19 is supplied conductive (amagnitude, amagnitude, conductive) plot of inductor 17, the impedance of the transducer 19 is sharply increases (decreases, increases), whereas the impedance of the transducer 18 is not changed, which means that changes the value and the polarity of V1 and V2, i.e. on the first information output 3 of the secondary Converter V1>0 (V1<0, V1<0, V1>0) and the second information output 4 of the secondary Converter V2<0 (V2>0, V2>0, V2<0).

The secondary Converter in figure 1 with the counter enabled secondary windings of unit transducers figure 3 operates as follows.

When submitting from the output of the source 5 harmonic or pulse signal in the positive half-cycle the current flows through the circuit: the first is the first clip of the source 5, the primary winding 20 of the first 18 primary Converter provisions common bus 10, the second clip channel 5; the second is the first clip of the source 5, the primary winding 22 19 second primary Converter provisions common bus 10, the second clip channel 5; the third, the first terminal of the secondary winding 21 of the first 18 of the transducer position, the diode 6, the element 15, the parallel connected resistor 11 and Conde who Sator 12, common bus 10, the second terminal of the secondary winding 21 of the first 18 of the transducer position; the fourth - first output of the secondary winding 23 of the second 19 of the transducer position, the diode 14, the element 16, the parallel connected resistor 8 and the capacitor 9, the common bus 10, the second terminal of the secondary winding 23 of the second 19 of the transducer position. In the negative half-cycle the current flows through the following circuit: first - second clip of the source 5, the common bus 10, the primary winding 20 of the first 18 of the transducer position, the first clamp source 5, the second - second clip of the source 5, the common bus 10, the primary winding 22 of the first 19 of the transducer position, the first clamping channel 5; the third, the second terminal of the secondary winding 21 of the first 18 primary Converter provisions common bus 10, the parallel connection of resistor 8 and capacitor 9, diode 7, the first terminal of the secondary winding 21 of the first 18 of the transducer position; a fourth the second terminal of the secondary winding 23 19 second primary Converter provisions common bus 10, parallel connected resistor 11 and capacitor 12, diode 13, the first terminal of the secondary winding 23 of the second 19 of the transducer position. The capacitors 12 and 9 respectively are formed voltages V1, V2 relative to a common bus 10. The value and polarity of these on the rajini depends on the position of the conductive area of the inductor 17, located on the inner or outer side of the primary converters regulations 18 and 19. Let the initial state, as shown in figure 5 (Fig.6, Fig.7, Fig), the minimum (maximum, maximum, minimum) mutual inductance of the first 18 and second 19 transducers as amagnitude (magnetic conductive, magnetic conductive, amagnitude) plot of the inductor 17 is in the area of 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 the second information output 4 of the secondary Converter V2<0 (V2<0, V2<0, V2<0). When moving inductor 17 figure 5 to the left (figure 6 right 7 right on Fig left) in the area of the primary Converter 18 is supplied conductive (amagnitude, amagnitude, conductive) plot of inductor 17, the mutual inductance of the primary transducer 18 increases (decreases, increases), while the state of the primary Converter 19 is not changed, which means that changes the value and the polarity of V1 and V2, i.e. on the first information output 3 of the secondary Converter V1>0 (V1<0, V1<0, V1>0) and the second information output 4 of the secondary Converter V2<0 (V2>0, V2>0, V2<0). When moving, and is the fountain roller 17 figure 5 to the right (figure 6 left 7 to the left, Fig right) in the area of the primary Converter 19 is supplied conductive (amagnitude, amagnitude, conductive) plot of inductor 17, the mutual inductance of the primary Converter 19 increases (decreases, increases), whereas the status of the primary transducer 18 is not changed, which means that changes the value and the polarity of V1 and V2, i.e. on the first information output 3 of the secondary Converter V1<0 (V1>0, V1>0, V1<0) and the second information output 4 the secondary Converter V2>0 (V2<0, V2<0, V2>0).

The secondary Converter in figure 1 in accordance with on the secondary windings of unit transducers figure 3 operates as follows.

When submitting from the output of the source 5 harmonic or pulse signal in the positive half-cycle the current flows through the circuit: the first is the first clip of the source 5, the primary winding 20 of the first 18 primary Converter provisions common bus 10, the second clip channel 5; the second is the first clip of the source 5, the primary winding 22 19 second primary Converter provisions common bus 10, the second clip channel 5; the third, the first terminal of the secondary winding 21 of the first 18 of the transducer position, the diode 6, the element 15, in parallel connected to the resistor 11 and the capacitor 12, shared the bus 10, the second terminal of the secondary winding 21 of the first 18 of the transducer position; the fourth - first output of the secondary winding 23 19 second primary Converter provisions common bus 10, parallel connected resistor 11 and capacitor 12, diode 13, the second terminal of the secondary winding 23 of the second 19 primary transducer position; fifth, the first terminal of the secondary winding 21 of the first 18 of the transducer position, the diode 6, the element 15, the diode 13, the second terminal of the secondary winding 23 of the second 19 of the transducer position, the first terminal of the secondary winding 23 of the second 19 of the transducer position, the second terminal of the secondary winding 21 of the first 18 primary transducer position. In the negative half-cycle the current flows through the following circuit: first - second clip of the source 5, the common bus 10, the primary winding 20 of the first 18 of the transducer position, the first clamp source 5, the second - second clip of the source 5, the common bus 10, the primary winding 22 of the second 19 of the transducer position, the first clamping channel 5; the third, the second terminal of the secondary winding 21 of the first 18 primary Converter provisions common bus 10, parallel connected resistor 8 and capacitor 9, diode 7, the first terminal of the secondary winding 21 of the first 18 of the transducer position; a fourth the second output of the secondary is th winding 23 19 second primary Converter provisions the diode 14, the element 16, the parallel connected resistor 8 and the capacitor 9, the common bus 10, the first terminal of the secondary winding 23 of the second 19 primary transducer position; fifth, the second terminal of the secondary winding 23 of the second 19 of the transducer position, the diode 14, the element 16, the diode 7, the first terminal of the secondary winding 21 of the first 18 of the transducer position, the second terminal of the secondary winding 21 of the first 18 of the transducer position, the first terminal of the secondary winding 23 of the second 19 of the transducer position. The capacitors 12 and 9 respectively are formed voltages V1, V2 relative to a common bus 10. The value and polarity of these voltages depend on the position of the conductive section of the inductor 17 on the inner or outer side of the primary converters regulations 18 and 19. Let the initial state, as shown in figure 5 (Fig.6, Fig.7, Fig), the minimum (maximum, maximum, minimum) mutual inductance of the first 18 and second 19 transducers as amagnitude (magnetic conductive, magnetic conductive, amagnitude) plot of the inductor 17 is in the area of 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 the second of information the m output 4 of the secondary Converter V2< 0 (V2<0, V2<0, V2<0). When moving inductor 17 figure 5 to the left (figure 6 right 7 right on Fig left) in the area of the primary Converter 18 is supplied conductive (amagnitude, amagnitude, conductive) plot of inductor 19, the mutual inductance of the primary transducer 18 increases (decreases, increases), while the state of the primary Converter 19 is not changed, which means that changes the value and the polarity of V1 and V2, i.e. on the first information output 3 of the secondary Converter V1>0 (V1<0, V1<0, V1>0) and the second information output 4 of the secondary Converter V2<0 (V2>0, V2>0, V2<0). When moving inductor 17 figure 5 to the right (figure 6 left 7 left on Fig right) in the area of the primary Converter 19 is supplied conductive (amagnitude, amagnitude, conductive) plot of inductor 17, the inductive coupling in the primary Converter 19 increases (decreases, increases), whereas the status of the primary transducer 18 is not changed, which means that changes the value and the polarity of V1 and V2, i.e. on the first information output 3 of the secondary Converter V1<0 (V1>0, V1>0, V1<0) and the second information output 4 of the secondary Converter V2>0 (V2<0, V2<0, V2>0).

Secondary is reobrazovateli in figure 1 with the counter enabled secondary windings of unit transducers figure 4 operates as follows.

When submitting from the output of the source 5 harmonic or pulse signal in the positive half-cycle the current flows through the circuit: the first is the first clip of the source 5, the primary winding 20 of the first 18 of the transducer position, the primary winding 22 19 second primary Converter provisions common bus 10, the second clip channel 5; second, the first terminal of the secondary winding 21 of the first 18 of the transducer position, the diode 6, the element 15, in parallel connected to the resistor 11 and the capacitor 12, the common bus 10, the second terminal of the secondary winding 21 of the first 18 of the transducer position; the third, the first terminal of the secondary winding 23 19 second primary Converter provisions, the diode 14, the element 16, the parallel connected resistor 8 and the capacitor 9, the common bus 10, the second terminal of the secondary winding 23 of the second 19 of the transducer position. In the negative half-cycle the current flows through the following circuit: first - second clip of the source 5, the common bus 10, the primary winding 22 of the second 19 of the transducer position, the primary winding 20 of the first 18 of the transducer position, the first clamping channel 5; the second terminal of the secondary winding 21 of the first 18 primary Converter provisions common bus 10, the parallel connected resistor 8 and capacitor 9, diode 7, the first terminal of the secondary winding 1 of the first 18 of the transducer position; the third, the second terminal of the secondary winding 23 19 second primary Converter provisions common bus 10, paralelno United resistor 11 and capacitor 12, diode 13, the first terminal of the secondary winding 23 of the second 19 of the transducer position. The capacitors 12 and 9 respectively are formed voltages V1 and V2 relative to a common bus 10. The value and polarity of these voltages depend on the position of the conductive section of the inductor 17 on the inner or outer side of the primary converters regulations 18 and 19. Let the initial state, as shown in figure 5 (Fig.6, Fig.7, Fig), the minimum (maximum, maximum, minimum) mutual inductance of the first 18 and second 19 transducers as amagnitude (magnetic conductive, magnetic conductive, amagnitude) plot of the inductor 17 is in the area of 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 the second information output 4 of the secondary Converter V2<0 (V2<0, V2<0, V2<0). When moving inductor 17 figure 5 to the left (figure 6 right 7 right on Fig left) in the area of the primary Converter 18 is supplied conductive (amagnitude, amagnitude, the conductive area of the inductor 17, the mutual inductance of the primary transducer 18 increases (decreases, increases), while the state of the primary Converter 19 is not changed, which means that changes the value and the polarity of V1 and V2, i.e. the first 3 informational output of the secondary Converter V1>0 (V1<0, V1<0, V1>0) and 4 on the second information output of the secondary Converter V2<0 (V2>0, V2>0, V2<0). When moving inductor 17 figure 5 to the right (figure 6 left 7 left on Fig right) in the area of the primary Converter 19 is supplied conductive (amagnitude, amagnitude, conductive) plot of inductor 17, the inductive coupling in the primary Converter 19 increases (decreases, increases), whereas the status of the primary transducer 18 is not changed, which means that changes the value and the polarity of V1 and V2, i.e. the first 3 informational output of the secondary Converter V1<0 (V1>0, V1>0, V1<0) and 4 on the second information output of the secondary Converter V2>0 (V2<0, V2<0, V2>0).

The secondary Converter in figure 1 when acquiescent inclusion of the secondary winding unit transducers figure 4 operates as follows.

When submitting from the output of the source 5 harmonic or pulse signal in the positive half-cycle the current flows is about circuits: the first the first clip source 5, the primary winding 20 of the first 18 of the transducer position, the primary winding 22 19 second primary Converter provisions common bus 10, the second clip channel 5; second, the first terminal of the secondary winding 21 of the first 18 of the transducer position, the diode 6, the element 15, the parallel connected resistor 11 and the capacitor 12, the common bus 10, the second terminal of the secondary winding 21 of the first 18 of the transducer position; the third, the first terminal of the secondary winding 23 19 second primary Converter provisions common bus 10, the parallel connected resistor 11 and capacitor 12, diode 13, the second terminal of the secondary winding 23 19 second primary Converter provisions; the fourth - first output of the secondary winding 21 of the first 18 of the transducer position, the diode 6, the element 15, the diode 13, the second terminal of the secondary winding 23 of the second 19 of the transducer position, the first terminal of the secondary winding 23 of the second 19 of the transducer position, the second terminal of the secondary winding 21 of the first 18 of the transducer position. In the negative half-cycle the current flows through the following circuit: first - second clip of the source 5, the common bus 10, the primary winding 22 of the second 19 of the transducer position, the primary winding 20 of the first 18 of the transducer position is tion, the first clip channel 5; the second terminal of the secondary winding 21 of the first 18 primary Converter provisions common bus 10, the parallel connected resistor 8 and capacitor 9, diode 7, the first terminal of the secondary winding 21 of the first 18 of the transducer position; the third, the second terminal of the secondary winding 23 of the second 19 of the transducer position, the diode 14, the element 16, paralelno United resistor 8 and the capacitor 9, the common bus 10, the first terminal of the secondary winding 23 19 second primary Converter provisions; the fourth is the second terminal of the secondary winding 23 19 second primary Converter provisions diode 14, the element 16, the diode 7, the first terminal of the secondary winding 21 of the first 18 of the transducer position, the second terminal of the secondary winding 21 of the first 18 of the transducer position, the first terminal of the secondary winding 23 of the second 19 of the transducer position. The capacitors 12 and 9 respectively are formed voltages V1 and V2 relative to a common bus 10. The value and polarity of these voltages depend on the position of the conductive section of the inductor 17 on the inner or outer side of the primary converters regulations 18 and 19. Let the initial state, as shown in figure 5 (Fig.6, Fig.7, Fig), the minimum (maximum, minimum, maximum) of the inductive the linkage between the primary and secondary windings of the first 18 and second 19 transducers provisions as amagnitude (magnetic conductive, magnetic conductive, amagnitude) plot of the inductor 17 is in the area of primary converters 18 and 19. This leads to the fact that the first 3 informational output of the secondary Converter V1<0 (V1<0, V1<0, V1<0) and 4 on the second information output of the secondary Converter V2<0 (V2<0, V2<0, V2<0). When moving inductor 17 figure 5 to the left (figure 6 right 7 right on Fig left) in the area of the primary Converter 18 is supplied conductive (amagnitude, amagnitude, conductive) plot of inductor 17, the inductive coupling in the primary transducer 18 increases (decreases, increases), while the state of the primary Converter 19 is not changed, which means that changes the value and the polarity of V1 and V2, i.e. the first 3 informational output of the secondary Converter V1>0 (V1<0, V1<0 That V1>0) and 4 on the second information output of the secondary Converter V2<0 (V2>0, V2>0, V2<0). When moving inductor 17 figure 5 to the right (figure 6 left 7 left on Fig right) in the area of the primary Converter 19 is supplied conductive (amagnitude, amagnitude, conductive) plot of inductor 17, the inductive coupling in the primary Converter 19 increases (decreases decrease the W increases), whereas the status of the primary transducer 18 is not changed, which means that changes the value and the polarity of V1 and V2, i.e. on the first information 3 the output of the secondary Converter V1<0 (V1>0, V1>0, V1<0) and the second information 4 the output of the secondary Converter V2>0 (V2<0, V2<0, V2>0).

The secondary Converter on 11 unit transducers in figure 2 operates as follows.

When submitting from the output of the source 5 time-varying signal in the positive half-cycle the current flows through the following circuit: - the first clip source 5, the winding 18 of the first primary Converter provisions, the diode 6, the element 15, the resistor 11, the common bus 10, the second clip channel 5; the second is the first clip of the source 5, the winding 18 of the first primary Converter provisions, the diode 6, the condenser 12, the common bus 10, the second clip channel 5; the third is the first clip of the source 5, the winding 19 of the first primary Converter provisions, the diode 14, the element 16, the resistor 8, the common bus 10, the second clip channel 5; the fourth is the first clip of the source 5, the winding 19 of the first primary Converter provisions, the diode 14, the capacitor 9, the common bus 10, the second clip channel 5. In the negative half-cycle the current flows through the following circuit: first - second clip of the source 5, the common bus 10, the resistor 11, the diode 13, the winding 19 Vtorov the primary transducer position, the first clip channel 5; the second - second clip of the source 5, the common bus 10, a condenser 12, the element 15, the diode 13, the winding 19 of the second primary Converter position, the first clamping channel 5; the third - second clip of the source 5, the common bus 10, the resistor 8, the diode 7, the winding 18 of the first primary Converter position, the first clamp source 5, the fourth - second clip of the source 5, the common bus 10, the capacitor 9, the element 16, the diode 7, the winding 18 of the first primary Converter position, the first clamp source 5. The capacitors 12 and 9 respectively are formed voltages V1, V2 relative to a common bus 10. The value and polarity of these voltages depend on the position of the conductive section of the inductor 17 on the inner or outer side of the primary converters regulations 18 and 19. Let the initial state, as shown in figure 5 (Fig.6, Fig.7, Fig), impedance of the transducer 18 position is approximately equal to the complex impedance of the transducer 19 of the regulations, as amagnitude (magnetic conductive, magnetic conductive, amagnitude) plot of the inductor 17 is in the area of 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 the second information output 4 in Orinoko Converter V2> 0 (V2<0, V2<0, V2>0). When moving inductor 17 figure 5 to the left (figure 6 right 7 right on Fig left) in the area of the primary Converter 18 is supplied conductive (amagnitude, amagnitude, conductive) plot of inductor 17, the impedance of the transducer 18 is sharply increases (decreases, increases), whereas the impedance of the transducer 19 is not changed, which means that changes the value and the polarity of V1 and V2, i.e. on the first information output 3 of the secondary Converter V1<0 (V1>0, V1>0, V1<0) and the second information output 4 of the secondary Converter V2>0 (V2<0, V2<0, V2>0). When moving inductor 17 figure 5 to the right (figure 6 left 7 left on Fig right) in the area of the primary Converter 19 is supplied conductive (amagnitude, amagnitude, conductive) plot of inductor 17, the impedance of the transducer 19 is sharply increases (decreases, increases), whereas the impedance of the transducer 18 is not changed, which means that changes the value and the polarity of V1 and V2, i.e. on the first information output 3 of the secondary Converter V1>0 (V1<0, V1<0, V1>0) and the second information output 4 wtorek the CSO Converter V2< 0 (V2>0, V2>0, V2<0).

All versions of the unit transducers for the basic circuit of the secondary of the Converter 1 is connected to a similar conclusion for the basic circuit of the secondary Converter figure 11.

In all versions of unit transducers provisions in this sensor there is a correlation channels, when the change of the impedance of one of the transducers affect the values of the voltages at the outputs of the secondary Converter. This effect is enhanced if the source is time-varying signal to use a current source. In this Converter the signs of the output voltage, which is informative parameter is not changed.

Thus, the above data confirm that the implementation of the use of the claimed invention, the following cumulative conditions:

the tool that performs the claimed invention in its implementation, is intended for use in industry, namely in measurement technology;

for the claimed invention in the form as it is described in the independent claims, confirmed the possibility of its implementation using the above described in the application or known before the priority date tools and methods;

- a means of embodying Appl the TES invention in its implementation, able to achieve a positive technical result.

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

Sources of information

1. U.S. patent No. 3688190, NC 324/61R, Ál G 01 R 27/26, August 29, 1972.

2. U.S. patent No. 3883812, NC 329/166, Ál H 03 D 1/10, may 13, 1975.

1. The three-position sensor for controlling the position containing block, consisting of two independent inductive (transformer) primary converters provisions impedance (mutual inductance) which varies with the movement of the controlled object, and the secondary Converter, the first and second outputs of which are connected respectively with the first and second inputs of unit transducers, the first and second outputs of which are connected respectively to first and second inputs of the secondary Converter having first and second information outputs and containing a source of time-varying signal, such as harmonic or pulse, the first and second terminals of which are connected to first and second outputs of the secondary Converter, respectively, the first input connected to the anode (cathode) of the first diode and the cathode (anode) of the second diode, the anode (cathode) which is connected to the first output of the second resistor, to the second information is th output of the secondary of the Converter and to the first output of the second capacitor, the second output of which is connected with the second output of the second resistor, with the second output of the secondary Converter, a shared bus, a 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 of the Converter and to the anode (cathode) of the third diode, the cathode (anode) which is connected to the second input of the secondary Converter and anode (cathode) of the fourth diode, wherein the introduction of two exemplary element, the first and second findings of the first model element connected respectively to the cathode (the anode of the first diode and to the anode (cathode) of the third diode, the first and second findings of the second exemplary element connected respectively to the cathode (the anode) of the fourth diode and to the anode (cathode) of the second diode.

2. The sensor according to claim 1, characterized in that the first and second exemplary element are resistors (inductance).

3. The sensor according to claim 1, characterized in that the first and second exemplary element are respectively a resistor (inductance) and inductance (resistor).

4. The sensor according to claim 1, characterized in that the block contains two independent primary inductive transducer position, the first conclusions of which is connected to the first input unit, to the first and second outputs of which p is soedinenii respectively second, the findings of the first and second independent inductive transducers provisions.

5. The sensor according to claim 1, characterized in that the block contains two independent transformer primary transducer position, each of which contains a primary and secondary winding, and the beginning (end) of the primary windings of the first and second independent transformer transducers position connected to the second input of unit transducers position, the first input connected to the ends (the basis) of the primary windings of the first and second independent transducers provisions, beginning (end) of the secondary winding of the first primary Converter provisions connected to the first output unit transducers position, the second output of which is connected to the beginning (end) of the secondary winding of the second independent of the transducer position, the end (beginning) of the secondary winding of which is connected to the end (beginning) of the secondary winding of the first primary transducer position and the second input unit independent transducers provisions.

6. The sensor according to claim 1, characterized in that the block contains two independent transformer primary transducer position, each of which contains a primary and secondary winding, and the beginning (end) of the primary winding of the first and the beginning (end) of the primary winding of the second independent TRANS is armaturnyh transducers position connected to the second input of unit transducers provisions 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 independent transducers position, the end (beginning) of the secondary winding of the first primary Converter provisions connected to the first output unit transducers position, 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 transducer position and the second input unit independent transducers provisions.

7. The sensor according to claim 1, characterized in that the block contains two independent transformer primary transducer position, each of which contains a primary and secondary winding, and the beginning (end) of the primary winding of the first and the end (beginning) of the primary winding of the second independent transformer transducers provisions 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 transducers provisions connected respectively to first and second inputs of unit transducers position, the first and the second output is which is respectively connected to the beginning (end) of the secondary winding of the first and beginning (end) of the secondary winding of the second independent transformer transducers provisions in which the end (beginning) of the secondary winding is connected to the second input transducers provisions.

8. The sensor according to claim 1, characterized in that the block contains two independent transformer primary transducer position, each of which contains a primary and secondary winding, and the beginning (end) of the primary winding of the first and the end (beginning) of the primary winding of the second independent transformer transducers provisions 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 transducers provisions connected respectively to first and second inputs of unit transducers position, the first and second outputs of which are respectively connected to the end (beginning) of the secondary winding of the first and the beginning of (end) of the secondary winding of the second independent transformer transducers position, in which the beginning (end) and the end (beginning) of the secondary winding is connected to the second input transducers provisions.

9. The three-position sensor for controlling the position containing block, consisting of two independent inductive (transformer) primary converters provisions impedance (voimaantulevat) which varies with the movement of the controlled object, and the secondary Converter, the first and second outputs of which are connected respectively with the first and second inputs of unit transducers, the first and second outputs of which are connected respectively to first and second inputs of the secondary Converter having first and second information outputs and containing a source of time-varying signal, such as harmonic or pulse, the first and second terminals of which are connected to first and second outputs of the secondary Converter, respectively, the first input connected to the anode (cathode) of the first diode and the cathode (anode) of the second diode, the anode (cathode) which is connected to the first output of the second resistor, the second information output of the secondary of the Converter is connected to the first output of the second capacitor, the second terminal of which is connected to the second output of the second resistor to the second output of the secondary of the Converter to a common bus, to the second output of the first resistor and to the second output of the first capacitor, a first output which is connected to the first information output of the secondary of the transformer and the cathode (the anode of the first diode, the first output of the first resistor is connected to anode (cathode) of the third diode, the cathode (anode) which is connected to the second input of the secondary Converter and anode (cathode) chetvertok the diode, the cathode (anode) which is connected to the first output of the second capacitor, wherein the two reference element, the first and second findings of the first model element connected respectively to the cathode (the anode of the first diode and to the anode (cathode) of the third diode, the first and second findings of the second exemplary element connected respectively to the cathode (the 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 (inductance).

11. The sensor according to claim 9, characterized in that the first and second exemplary element are respectively a resistor (inductance) and inductance (resistor).

12. The sensor according to claim 9, characterized in that the block contains two independent inductive transducers position, the first conclusions of which is connected to the first input unit, to the first and second outputs of which are connected respectively to the second, the findings of the first and second independent inductive transducers provisions.

13. The sensor according to claim 9, characterized in that the block contains two independent transformer primary transducer position, each of which contains a primary and secondary winding, and the beginning (end) of the primary windings of the first and second independent transformer pri is cnyh converters provisions connected to the second input of unit transducers provisions first input connected to the ends (the basis) of the primary windings of the first and second independent transducers provisions, beginning (end) of the secondary winding of the first primary Converter provisions connected to the first output unit transducers position, 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 end (beginning) of the secondary winding of the first primary transducer position and the second input unit independent transducers provisions.

14. The sensor according to claim 9, characterized in that the block contains two independent transformer primary transducer position, each of which contains a primary and secondary winding, and the beginning (end) of the primary winding of the first and the beginning (end) of the primary winding of the second independent transformer transducers position connected to the second input of unit transducers position, the first input connected to the end (beginning) of the primary winding of the first and the end (beginning) of the primary winding of the second independent transducers position, the end (beginning) of the secondary winding of the first primary Converter provisions attached to the first unit output transducers provisions, 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 transducer position and the second input unit independent transducers provisions.

15. The sensor according to claim 9, characterized in that the block contains two independent transformer primary transducer position, each of which contains a primary and secondary winding, and the beginning (end) of the primary winding of the first and the end (beginning) of the primary winding of the second independent transformer transducers provisions 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 transducers provisions connected respectively to first and second inputs of unit transducers position, the first and second outputs of which are respectively connected to the beginning (end) of the secondary winding of the first and the beginning of (end) of the secondary winding of the second independent transformer transducers position in which the end (beginning) of the secondary winding is connected to the second input transducers provisions.

16. The sensor according to claim 9 characterized in that the unit contains two independent transformer primary transducer position, each of which contains a primary and secondary winding, and the beginning (end) of the primary winding of the first and the end (beginning) of the primary winding of the second independent transformer transducers provisions 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 transducers provisions connected respectively to first and second inputs of unit transducers position, the first and second outputs of which are respectively connected to the end (beginning) of the secondary winding of the first and the beginning (end) of the secondary winding of the second independent transformer transducers position, in which the beginning (end) and the end (beginning) of the secondary winding is connected to the second input transducers provisions.

 
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