RU2053712C1 - Method for balancing ferroprobe with two coaxial sensory members - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: method involves directing sensory members in the direction of maximum value of false signal followed with its compensation. To do it, compensation plane position is determined with Permalloy core which axis is in perpendicular to longitudinal axis of the ferroprobe by means of its approaching to one of the sensory member ends to determine the magnitude of the core action exerted upon the sensory member , rotating the ferroprobe about its longitudinal axis until the maximum signal is detected. Compensation is carried out by using the same Permalloy core, which axis belongs to the compensation plane, by means of its approaching the other end of the sensory member and using another Permalloy core which axis is coaxial with the longitudinal ferroprobe axis and belonging to the compensation plane. The Permalloy cores are approached by means of a device made in form of bushing with holes, the axis of one of which is set in perpendicular to the longitudinal axis and belongs to the same plane. EFFECT: enhanced accuracy of balancing. 2 cl, 1 dwg

Description

 The invention relates to medicine, in particular to ophthalmology, and is intended for the localization of intraocular foreign ferromagnetic bodies, and can also be used in measuring equipment for non-destructive quality control of materials.

 To localize foreign ferromagnetic bodies, flux-gate poles are used to find magnetic poles by small magnetic field inhomogeneities.

 Currently, in medical practice, the use of pole-seekers is limited.

 This is due to the technological complexity of obtaining the given electrical parameters of flux gates, the violation of which entails the rejection of the product or the appearance of a significant magnitude of the proper signal that imitates the presence of a foreign ferromagnetic body near the flux gate, which significantly reduces the efficiency of the use of pole detectors.

 The occurrence of a false signal is due to the presence of both a transverse homogeneous geomagnetic field and the non-parallelism of the magnetic axes of the flux-gate cores, as well as a longitudinal homogeneous geomagnetic field and the non-identical transformation coefficients of the semi-elements of the flux-gate.

 At present, the specified electrical parameters of flux gates are achieved in the assembly process by balancing (tuning) half elements using permalloy cores (1). The balancing is carried out in such a way that, in the absence of the influence of the inhomogeneity of the magnetic field (foreign ferromagnetic body) on the half elements of the flux gate, when the horizontal component of the full vector of the geomagnetic field is located in the transverse direction, the minimum voltage, called the initial unbalance voltage, is present at the output of the half elements of the flux gate. When balancing fluxgates, a circuit consisting of a generator, a frequency meter, a millivoltmeter, a microvoltmeter, and an oscilloscope is used. Balancing is performed at a certain excitation current and frequency, when the board with the coils is located orthogonally to the horizontal component of the full vector of the geomagnetic field. The cores in the coils are installed and moved using pieces of fiberglass with a diameter of 15-30 microns, on which they are attached with BF-4 glue. The cores are introduced into the coils and moved so that the emf of the unbalance in the second harmonic is no more than 1 mV, then the cores in the coils are fixed with BF-4 glue.

The disadvantages of this balancing method are as follows:
in complex balancing technology, as a result of which the production of flux gates in the factory is difficult;
in a change in the angle of non-parallelism of the magnetic axes of the flux-gate cores (i.e., in a change in the magnitude of the false signal) after fixing the cores with glue, as a result of the uneven drying of the glue.

 A known method of balancing a flux-gate based on the selection of half-elements of a flux-gate (i.e., on the selection of cores and coils) (2).

 The balancing of the flux gate is carried out as follows. A sinusoidal voltage (main) is supplied to the excitation circuit, which is sufficient for magnetization reversal of the cores. In practice, this voltage contains in addition to the first harmonic and others, including the second, on which, as a rule, flux gates operate. In addition, an additional sinusoidal voltage is applied to the excitation circuit, which is close in frequency to the second harmonic of the main voltage (10-15 Hz difference). Due to the non-identity of the semi-elements, the emf of a false signal appears at the output of the flux gate, which in its spectrum has harmonics of the frequency of the main and additional voltage. The selection of the half elements according to the minimum values of the harmonics of the main voltage does not exclude the penetration of the "false" second harmonic of the excitation frequency from the excitation circuit into the output circuit. Therefore, the selection of the semi-elements is carried out by the minimum value of the additional voltage in the output EMF of the flux-gate, the frequency of which is close to the second harmonic of the main voltage. As a result, the penetration of the “false” second harmonic from the excitation circuit into the output circuit of the flux gate is excluded.

The disadvantages of this balancing method are:
sophisticated balancing technology;
the need for the selection of half elements at the test bench;
the limited possibility of this balancing method, since it is no longer possible to carry out additional balancing of the flux-gate by the method considered earlier (1).

 The closest technical solution, selected as a prototype, is a balancing method based on the introduction of an additional flux gate into the flux gate, eliminating the false signal due to the presence of a transverse homogeneous geomagnetic field and non-parallelism of the flux gate cores (magnetic axes of the flux gate cores) (3).

 This balancing method is used in geophysical equipment.

 The balancing of the flux gate is carried out as follows.

The main fluxgate (consisting of two semi-elements mounted on the block) is oriented in a horizontal plane in the north-south direction. Then the fluxgate is rotated around its longitudinal axis to determine the position in which the spurious signal has a maximum value (the fluxgate is rotated in the horizontal plane with a change in the rotation angle within ± 180 ^° ). In this position, a flux gate is fixed and an additional flux gate is installed, orienting it vertically Z. Compensation of the false signal is carried out by a potentiometer, followed by replacement with a variable or constant resistor resistance.

The disadvantages of this balancing method are the following:
the difficulty of balancing the additional flux gate (since to completely eliminate the false signal, it is necessary to balance the additional flux gate in the plane of the maximum magnitude of the false signal, and this is technologically difficult, but it is especially difficult to balance the additional flux gate in small-sized flux gates);
complicating the balancing of the flux gate with the introduction of another flux gate, for example, to eliminate the false signal associated with the non-identical half-elements of the flux gate.

 The technical result is to simplify and increase the degree of balancing of the flux gate by introducing compensation cores into the flux gate, determining the compensation plane and compensating for the false signal due to the presence of both a transverse uniform geomagnetic field and non-parallelism of the flux-gate cores, and a longitudinal uniform geomagnetic field, and non-identical half-cell conversion coefficients fluxgate.

 The technical result is achieved due to the fact that in the method of balancing a flux gate with two coaxially located sensitive elements by orienting them in the direction corresponding to the maximum value of the false signal, followed by compensation, the position of the compensation plane is determined before the latter using a permalloy core, the axis of which is perpendicular to the longitudinal axis a flux-gate, by bringing it to one of the ends of the sensitive element with determining the magnitude of the signal from the influence of the heart nickel on the sensitive element, rotation of the flux gate around its longitudinal axis until the maximum signal value appears, and compensation is carried out by bringing the same permalloy core, whose axis lies in the compensation plane, to the other end of the sensitive element, and an additional permalloy core with the axis, coaxial with the longitudinal axis of the flux-gate and lying in the compensation plane. Moreover, the supply of permalloy cores is carried out using a device made in the form of a sleeve with holes, the axis of one of which coincides with the longitudinal axis of the sleeve, and the axes of the other two are perpendicular to the longitudinal axis and lie in the same plane.

 The implementation scheme of the proposed balancing method is presented in the drawing.

 The balancing of the flux gate is as follows.

 The flux gate 1 is placed in a magnetostatic screen and a null point is set (i.e., zero correction is performed), removed from the screen and oriented in a horizontal plane in the direction where the null point remains unchanged (the zero point is controlled by the pointer indicator of the detector). A compensating permalloy core 6 is introduced into the hole 9 located in the handle of the fluxgate 8 orthogonally to one of the ends of one of the cores of the fluxgate 5 to determine the compensation plane Z, in which the false signal is completely compensated. To do this, the signal value characterizing the influence of the scattering field of the compensation core 6 on the core of the flux probe 5 is fixed (with a pointer indicator). After that, the flux probe 1 (relative to the compensation core 6) is rotated around its longitudinal axis until the maximum value of the signal, which indicates the orthogonal location of the compensation plane, is detected Z, which passes through one of the ends of the core of the fluxgate 5, which is at a minimum distance from the compensation core 6. After this, the the sensing core 6 is removed from the indicator hole 9 and the fluxgate is oriented in a horizontal plane in the north-south direction to detect the maximum value of the false signal due to the presence of a transverse geomagnetic field and the core of the fluxgate 4 and 5 are not parallel, the fluxgate 1 is fixed in this position and the compensation core 6 is inserted into the compensation hole 10, which is located in the handle of the fluxgate 8, in line with the indicator hole 9, in the found compensation plane Z, orthogonal to the other end of the same core of the fluxgate 5, to eliminate the false signal.

 The balancing of a flux gate associated with the elimination of a false signal due to the presence of a longitudinal homogeneous geomagnetic field and the non-identity of the conversion coefficient of the semi-elements of the flux gate is carried out as follows. The longitudinal axis X of the fluxgate 1 is oriented vertically to identify the maximum value of the false signal, then an additional compensation core 7 is inserted into the hole 11 located coaxially to the half-element of the fluxgate 3,5 in the compensation plane passing through the longitudinal axis X of the half-elements of the fluxgate 2,4 and 3, 5 to eliminate the false signal.

 When the scattering field of the additional compensation core 7 affects the compensation core 6, the balancing of the flux gate is carried out similarly to the described actions, however, balancing operations begin from the hole 10 located in the handle of the flux gate 8.

 Using the method of balancing a fluxgate allows (in comparison with the known methods) to significantly simplify balancing and at the same time, without complicating the operation, increase the degree of balancing of the fluxgate, and this leads to a decrease in labor intensity, to an increase in the efficiency of the use of the pole detector, to the application of this method in other designs of fluxgates.

Claims (2)

 1. METHOD FOR BALANCING A FERROBOUND WITH TWO CONJECTIVELY SITUATED SENSITIVE ELEMENTS by orienting them in the direction corresponding to the maximum value of the false signal, followed by compensation, characterized in that before the compensation, the position of the compensation plane is determined using a permalloy core with a perpendicular axis whose axis bringing it to one of the ends of the sensitive element with determining the magnitude of the signal from the influence of the core on the sensitive element ent, rotation of the flux gate around its longitudinal axis until the maximum signal value appears, and compensation is carried out by bringing the same permalloy core, the axis of which lies in the compensation plane, to the other end of the sensor element and an additional permalloy core with an axis coaxial with the longitudinal axis of the flux probe lying in the compensation plane.  2. The method according to p. 1, characterized in that the permalloy cores are supplied using a device made in the form of a sleeve with holes, the axis of one of which coincides with the longitudinal axis of the sleeve, and the axes of the other two are perpendicular to the longitudinal axis and lie in the same plane .

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