RU2152624C1 - Variable electromagnetic field magnetic- component intensity meter - Google Patents

Abstract

FIELD: measurement technology. SUBSTANCE: meter has series-connected main antenna, adjustable amplifier, detector, indicator, and calibrating antenna connected to output of adjustable calibrating generator; calibrating antenna is mounted as close as possible and symmetrically to main antenna; for example, winding circuits of calibrating antenna can be placed above or between winding turns of main antenna uniformly and symmetrically to its turns. EFFECT: improved accuracy and facilitated measurement procedure; simplified design. 2 dwg

Description

 The invention relates to the field of radio measurements, more precisely, to the measurement of alternating electromagnetic fields, and is intended for use in electromagnetic field meters that do not require periodic verification from an external source of a standard electromagnetic field.

 The prior art.

 Various methods are known for measuring the intensity of magnetic components of variable electromagnetic fields [1-7]. In particular, in the book of E. T. Chernyshev, N. G. Chernyshev and others. "Magnetic measurements", Moscow, ed. Standards, 1969, pp. 32-36 [1] describes a measurement method by converting the magnetic component of the electromagnetic field to an alternating voltage, the magnitude of the alternating voltage being proportional to the magnetic component of the electromagnetic field. Moreover, depending on the purpose, the measuring transducers differ in geometric dimensions, number of turns and shape (cylindrical, in the form of a ball, square, rectangular cross-section of frames).

 The most common block diagram of a variable electromagnetic field meter is a series-connected main antenna (a reversible transducer of an electromagnetic field to an electric signal) 1, an adjustable amplifier 2, a detector 3, and an indicating device 4. In this case, the main antenna (a reversible transducer) 1 is usually made as small as possible . This diagram is presented in the drawing and is described in detail, for example, in [2] - V.V. Panin, B.I. Stepanov "Measurement of pulsed magnetic and electrical noise", Moscow: Energoatomizdat, 1983, p. 32.

 The meter works as follows. Before starting operation (and also subsequently periodically), the meter is calibrated, i.e. set the fixed sensitivity of the meter. To do this, the main antenna 1 of the meter is placed in a standard alternating electromagnetic field formed by a special driver of a uniform alternating electromagnetic field, for example, coaxially mounted solenoids in the working volume of Helmholtz rings or Maxwell rings [1], on the axis of which a uniform alternating magnetic field is formed upon their synchronous excitation .

 The main antenna 1 converts the electromagnetic field strength into an electric signal, which is amplified by an adjustable amplifier 2, then goes to a detector 3, the output signal of which excites the indicating device 4. In this case, by changing the gain of the adjustable amplifier 2, the readings of the indicating device 4 correspond to the known standard variable electromagnetic field created by field formers. Thus, the meter readings (sensitivity) are set.

 Then the measuring device can be used for its intended purpose - for measuring variable electromagnetic fields of unknown magnitude. To do this, place the main antenna 1 in the place where you want to measure. The intensity of the external measured alternating magnetic field is converted by the main antenna 1 into an electrical signal, which is amplified by the amplifier 2, then fed to the detector 3, the output of which is connected to the indicating device 4.

 It is also known that all measuring devices must periodically re-set the readings (sensitivity) in predetermined standard uniform variable electromagnetic fields (similar to those described above) in special centers to obtain a predetermined guaranteed measurement accuracy. In particular, this periodic verification and adjustment should eliminate temporary and operational changes in the elements of the field meter — the size and orientation of the antenna, the characteristics of the antenna material, amplification and detector elements, and the indicating device. As follows from the example described above, this verification for a magnetic field meter is rather complicated, because requires special bulky and expensive equipment - a shaper of a uniform alternating electromagnetic field of a predetermined intensity. As an example of such a shaper, there may be Helmholtz rings or Maxwell rings. It is a ring, coaxially located at a distance of the diameter of these rings, which filed with variable excitation.

 The need for periodic calibration of the meter in stationary conditions of a special center complicates the operation process. In addition, the accuracy of measurements depends on changes in the external conditions in which the meter is located - pressure, humidity, temperature, and the presence of interfering emissions. These errors cannot be eliminated in known meters even by periodically adjusting the sensitivity, since in this case a standard uniform field shaper would have to be in place of the measurement.

To reduce these shortcomings, the following measures are usually used:
design of time-stable antennas, amplifiers, detectors, indicating instruments,
the same with changes in temperature, humidity, pressure,
shielding of the meter and its elements,
temperature control of the meter and its elements,
introduction of additional measurement channels (for comparison),
Frequent sensitivity testing in specially equipped test centers
and other measures described in detail, for example, in [1].

 However, the listed means and measures of the road complicate the device, the measurement process and do not completely eliminate doubts about the accuracy of the measurements.

 Closest to the claimed device is a meter shown in the drawing and selected by us as a prototype. It is described in detail in [2]. As shown above, it consists of a main antenna 1, the output of which is connected to the input of an adjustable amplifier 2, the output of which through the detector 3 is connected to the indicating device 4.

 The objective of the invention is to improve the accuracy and convenience of measurements, as well as simplifying the device.

 SUMMARY OF THE INVENTION

The problem is solved in that in the known meter of magnetic component strength of an alternating electromagnetic field containing series-connected main antenna (reversible electromagnetic converter), an adjustable amplifier, detector and indicating device, significant changes and additions have been made, namely -
an amplitude-controlled calibration generator and a calibration antenna (reversible electromagnetic transducer) connected to the output of the calibration generator are introduced into it.

 In addition, to further improve accuracy, the calibration antenna can be placed as close to the main antenna as possible.

 In addition, to simplify the meter, the turns of the calibration antenna can be placed evenly on or between the turns and symmetrically with respect to the turns of the winding of the main antenna (reversible transducer).

 Disclosure of the invention.

 The invention is illustrated by the following example of a structural diagram of a meter for measuring the magnetic component of an alternating electromagnetic field, where 1 is the main antenna, 2 is an adjustable amplifier, 3 is a detector, 4 is an indicating device, 5 is an adjustable calibration generator, 6 is a calibration antenna.

 The meter is a series-connected main antenna 1, an adjustable amplifier 2, a detector 3, and an indicating device 4. A calibration adjustable generator 5 is connected to a calibration antenna 6 located symmetrically and possibly close to the main antenna 1.

 The meter works as follows. When the sensitivity of the meter is initially set, its main antenna 1 is placed in a standard external uniform electromagnetic field of a given strength, formed, for example, by Maxwell rings in accordance with [1].

 When the specified standard uniform alternating electromagnetic field of a given voltage acts on the main antenna 1 of the meter, it is converted into an electric signal, which is amplified by an adjustable amplifier 2, detected by a detector 3 and excites a indicating device 4. By changing the transmission coefficient of the amplifier 2, an electrostatic field meter is installed on the indicating device 4 reading corresponding to the specified intensity of the external standard electromagnetic field.

 Then, the external generator of the standard uniform variable electromagnetic field is turned off (the external field is removed) and the calibration adjustable generator 5 is inserted into the magnetic field meter according to the invention. Its frequency is the same as that of an external generator of a standard electromagnetic field. The output voltage of the adjustable calibration generator 5 is supplied to the calibration antenna 6 and forms an electromagnetic field around the calibration antenna, since it is a reversible electromagnetic transducer. The intensity of the electromagnetic field created by the calibration generator 5 and its antenna 6 acts on the main antenna 1, is converted into a corresponding electrical signal in it, is amplified by an adjustable amplifier 2, the amplified signal (proportional to the electromagnetic field created by the calibration circuit 5-6) acts through the detector 3 showing device 4. By changing the amplitude of the output signal of the calibrated adjustable generator 5, the readings of the indicating device 4 are achieved, equal to the readings e were on it when exposed to a standard meter external alternating electromagnetic field strength and a predetermined fixed level calibration signal controlled oscillator 5.

 The proposed solution is new because it is unknown from available sources of information.

 In fact, through the calibration generator 5 and the calibration antenna 6, an alternating electromagnetic field is formed, the total effect of which on the main antenna 1 is similar to the effect of a standard uniform electromagnetic field of a given strength. Moreover, the created calibration electromagnetic field is certainly uneven and in shape very different from the specified uniform standard, but it is exactly equivalent to it in the only parameter we need - it causes the same electrical signal in the main antenna 1. This property is used in the inventive meter for continuous operational calibration of the meter and timely correction of changes in the parameters of all its elements associated with aging, temperature, pressure and shaking.

 The proposed solution is not obvious to the specialist, as does not follow explicitly from the prior art.

 Naturally, the closer the calibration antenna is to the main antenna, the closer the generated field will be to the standard field.

 Then, during operation, before each measurement of the magnetic component strength of the alternating external alternating electromagnetic field, the meter is first screened from strong external alternating electromagnetic fields, the calibration adjustable oscillator 5 is built into the meter and the level fixed at the meter’s initial sensitivity setting is set at its output. Then, by changing the gain of the adjustable amplifier 2, the readings of the indicating device 4 are set equal to the readings at the initial sensitivity setting. Then turn off the built-in calibration adjustable generator 5, install the main antenna 1 of the meter at the measurement point and measure the magnetic field leaving an alternating electromagnetic field. At the same time, the accuracy of the measurement is guaranteed by calibration performed immediately before the actual field measurement.

 Industrial applicability.

 The claimed device is feasible means well mastered by the industry. In particular, a reversible converter (antenna) 1 can be made in the form of a coil of copper wire wound around a polystyrene frame, an amplifier, a detector, and a generator — on operational amplifiers, showing a device — pointer or digital, and regulators — potentiometers. The magnetic field strength meter using the described invention was built at the applicant enterprise, named PIMA, successfully passed the tests and is already being delivered to consumers. However, no practical difficulties associated with the use of the invention were encountered.

 Thus, in our opinion, the claimed technical solution meets all the criteria for inventions - it is new, non-obvious and industrially applicable.

Literature
1. E.T. Chernysheva, N.G. Chernysheva et al. "Magnetic measurements", Moscow, ed. Standards, 1969, pp. 32-36.

 2. V.V. Panin, B.I. Stepanov. "Measurement of pulsed magnetic and electrical noise", M .: Energoatomizdat, 1983, p. 32 - prototype.

 3. A.S. USSR N 721784, BI N 10, 1980, MKI G 01 R 33/02.

 4. A.s. USSR N 758021, BI N 31, 1980, MKI G 01 R 33/02.

 5. A.S. USSR N 1188681, BI N 40, 1985, MKI G 01 R 33/02.

 6. A.S. USSR N 720382, BI N 9, 1980, MKI G 01 R 33/02.

 7. A.S. USSR N 792181, BI N 48, 1980, MKI G 01 R 33/02.

Claims (1)

 The meter of the magnetic component of the variable electromagnetic field containing the main antenna in series, an adjustable amplifier, detector and indicating device, as well as a calibration antenna connected to the output of the calibration generator, characterized in that the calibration generator is adjustable, the calibration antenna is placed as close as possible and symmetrically to the main antenna, for example, the turns of the winding of the calibration antenna are placed on top of or between the turns of the winding of the main antenna - uniformly and symmetrically with respect to its turns.