RU85682U1 - AMPLIFIED FREQUENCY METAL DETECTOR - Google Patents

Abstract

An amplitude-frequency metal detector containing an inductive metal sensor, a sinusoidal voltage generator, an amplitude detector, a first low-pass filter and an amplitude deviation amplifier connected in series, a frequency detector, a second low-pass filter and a frequency deviation amplifier connected in series, characterized in that it further comprises an adder, a device for comparing relative amplitudes and an indicator of the type of metal, connected in series, and the input of the frequency detector under is connected to the output of the sinusoidal voltage generator, the first adder input is connected to the output of the amplitude deviation amplifier, the second adder input and the second input of the relative amplitude comparison device are connected together and connected to the output of the frequency deviation amplifier, the adder output is connected to the first input of the relative amplitude comparison device, the output of which connects to a metal type indicator.

Description

The utility model relates to devices for detecting metal objects, and can be used to selectively search for hidden metal objects in various industries

A known resonant metal detector containing a sinusoidal voltage generator, an amplitude detector, a low-pass filter, a pulse amplifier and an actuator (Utility Model Certificate No. 19329, MKI G01V 3/10, 2001).

A disadvantage of the known metal detector is the lack of selectivity for ferrous and non-ferrous metals, which makes it impossible to assess the type of metal found in the soil of an object without excavation, and reduces the effectiveness of a targeted search for objects from metals of a certain type.

The closest technical solution to the proposed design of the utility model is a selective resonant metal detector containing an inductive metal sensor, a sinusoidal voltage generator, an amplitude detector, a low-pass filter and a pulse amplifier connected in series, as well as a frequency detector, soil mineralization compensator and a metal type indicator connected sequentially, and the input of the frequency detector is connected to the output of the sinusoidal voltage generator, the first input will compensate pa mineralization connected to the output of the frequency detector, a second input coupled to the output of the pulse amplifier and to the output of the compensator is connected mineralization of soil type metal indicator. In this case, the soil mineralization compensator consists of a controllable memory element and a differential adder, the first input of the controllable memory element and the non-inverting input of the differential adder connected together, and the output of the controllable memory element connected to the inverting input of the differential adder (Utility Model Patent No.58227, IPC G01V 3/10 2006 01)

The disadvantage of this metal detector is the lower restriction on the movement speed of the inductive metal sensor due to the fixed value of the memory time of the controlled memory element, as well as the need to move the sensor strictly parallel to the soil surface above a metal object located in the soil with a high content of distributed metal minerals or electrically conductive salts, to maintain a stable signal level from the ground at the non-inverting input of the differential adder in those the response time of the controlled memory element.

The claimed utility model is based on the task of developing a metal detector design that improves the reliability of detecting metal objects in various types of soils by introducing compensation for soil mineralization and selectivity for ferrous and non-ferrous metals.

In the claimed design of the utility model, this is achieved due to the fact that the amplitude-frequency metal detector containing an inductive metal sensor, a sinusoidal voltage generator, an amplitude detector, a first low-pass filter and an amplitude deviation amplifier connected in series, a frequency detector, a second low-pass filter and an amplifier frequency deviations connected in series, further comprises an adder, a device for comparing relative amplitudes and an indicator of the type of metal, connected therefore, the input of the frequency detector is connected to the output of the sinusoidal voltage generator, the first input of the adder is connected to the output of the amplitude deviation amplifier, the second input of the adder and the second input of the relative amplitude comparison device are connected together and connected to the output of the frequency deviation amplifier, the output of the adder is connected to the first input of the device comparing relative amplitudes, the output of which is connected to an indicator of the type of metal.

The analysis of patent and scientific and technical literature showed that the claimed design of the utility model was not described in the literature and contains distinctive features in comparison with known analogues

The drawing shows a functional diagram of an amplitude-frequency metal detector.

An inductive metal sensor 1, a sinusoidal voltage generator 2, an amplitude detector 3, a first low-pass filter 4 and an amplitude deviation amplifier 5 are connected in series. The frequency detector 6, the second low-pass filter 7 and the frequency deviation amplifier 8, are connected in series. The adder 9, a device for comparing relative amplitudes 10 and an indicator of the type of metal 11 are connected in series.

The input of the frequency detector 6 is connected to the output of the sinusoidal voltage generator 2, the first input of the adder 9 is connected to the output of the amplitude deviation amplifier 5, the second input of the adder 9 and the second input of the relative amplitude comparison device 10 are connected together and connected to the output of the frequency deviation amplifier 8, the output of the adder 9 connected to the first input of the device for comparing relative amplitudes 10, and an indicator of the type of metal 11 is connected to its output.

The amplitude-frequency metal detector operates as follows.

In the initial state, in the absence of metal objects and mineralized soil near the inductive sensor 1, the sinusoidal voltage generator 2 generates an alternating voltage with a fixed amplitude and frequency, which are determined by the parameters of the inductive metal sensor 1, as a result of which there are no signals at the outputs of the amplitude detector 3, the first low filter frequency 4, an amplifier of amplitude deviations 5, a frequency detector 6, a second low-pass filter 7, an amplifier of frequency deviations 8, an adder and 9 and devices for comparing relative amplitudes 10, as a result of which the indicator of the type of metal 11 is inoperative.

When a metal object appears near the inductive metal sensor 1, in the absence of mineralized soil, the amplitude of the alternating voltage at the output of the sinusoidal voltage generator 2 decreases due to the introduced resistance. The amplitude detector 3 emits an envelope of the amplitude of the alternating voltage. The first low-pass filter 4 emits a useful signal and cuts off interference signals. The amplifier of amplitude deviations 5 amplifies the signal to the level necessary for operation of the adder 9 and the device for comparing relative amplitudes 10. Moreover, the polarity of the signal at the output of the amplifier of amplitude deviations 5 does not depend on the type of metal and has a negative value. At the same time, due to a change in the inductance of the metal sensor 1, the frequency of the alternating voltage at the output of the sinusoidal voltage generator 2 is changed. The frequency detector 6 converts the change in the frequency of the alternating voltage supplied to its input into a change in the amplitude of the signal at its output. The second low-pass filter 7 emits a useful signal and cuts off interference signals. The frequency deviation amplifier 8 amplifies the signal to the level necessary for operation of the adder 9 and the relative amplitude comparison device 10. Moreover, the polarity of the signal at the output of the frequency deviation amplifier 8 depends on the type of metal, a negative value for ferrous metals and a positive value for non-ferrous metals. If an object of ferrous metal appears near the inductive metal sensor 1, the signal of negative polarity from the output of the frequency deviation amplifier 8 is fed to the second input of the device for comparing relative amplitudes 10 and to the second input of the adder 9. At the same time, the negative polarity signal is output from the output of the adder 9 the amplifier of amplitude deviations 5. As a result, the total signal from the output of the adder 9 to the first input of the device for comparing relative amplitudes 10 exceeds I drove arriving at its second input. As a result of this, at the output of the device for comparing relative amplitudes 10, a signal of negative polarity appears, which is fed to the input of a metal type indicator 11, which displays the presence of an object made of ferrous metal. In the event that an object of non-ferrous metal appears near the inductive metal sensor 1, the signal of positive polarity from the output of the frequency deviation amplifier 8 is fed to the second input of the device for comparing relative amplitudes 10 and to the second input of the adder 9. At the same time, a negative polarity signal is output from the output of the adder 9 amplitude deviation amplifier 5. As a result, the total signal from the output of the adder 9 to the first input of the device for comparing relative amplitudes 10, due to the addition of different Yarnykh signals has a value smaller compared with the signal entered at its second input. As a result of this, at the output of the device for comparing relative amplitudes 10, a signal of positive polarity arrives at the input of a metal type indicator 11, which displays the presence of an object of non-ferrous metal.

When moving the inductive metal sensor 1 above the soil surface with increased mineralization, in the absence of metal objects near the inductive metal sensor 1, the amplitude of the alternating voltage at the output of the sinusoidal voltage generator 2 remains unchanged. As a result, there is no signal at the outputs of the amplitude detector 3, the first low-pass filter 4 and the amplifier of amplitude deviations 5. At the same time, the frequency of the alternating voltage at the output of the sinusoidal voltage generator 2 varies depending on the degree of mineralization of the soil, resulting in the output of the frequency detector 6 a signal appears whose amplitude is proportional to the degree of mineralization. The second low-pass filter 7 emits a useful signal and cuts off interference signals. The amplifier of frequency deviations 8 amplifies the signal to the level necessary for operation of the adder 9 and the device for comparing relative amplitudes 10. A signal proportional to the degree of mineralization of the soil comes from the output of the amplifier of frequency deviations 8 to the second input of the device for comparing relative amplitudes 10 and to the second input of the adder 9. Due to the fact that there is no signal at the first input of adder 9, identical signals with the same amplitudes arrive at the first and second inputs of the device for comparing relative amplitudes 10 Doi and polarity. As a result of this, the signal at the output of the device for comparing relative amplitudes 10 is absent and the indicator of the type of metal 11 is inoperative.

When a metal object located in the soil with increased mineralization appears near the inductive sensor of metal 1, the amplitude of the alternating voltage decreases at the output of the sinusoidal voltage generator 2, the amplitude detector 3 selects the envelope of the amplitude of the alternating voltage, the first low-pass filter 4 emits a useful signal and cuts off interference signals as a result of which the output of the amplifier of amplitude deviations 5 receives a signal of negative polarity at the first input of the adder 9. Additional and the change in the frequency of the alternating voltage at the output of the sinusoidal voltage generator 2, caused by the appearance of a metal object, is converted in the frequency detector 6 into an additional change in the amplitude at its output. The second low-pass filter 7 selects the useful signal and cuts off the interference signals, the frequency deviation amplifier 8 amplifies the additional change in the signal amplitude to the level necessary for operation of the adder 9 and the relative amplitude comparison device 10. As a result, the second relative amplitude comparison device 10 and the second the adder 9 input, an additional change in the signal amplitude is received, the polarity of which corresponds to the type of metal, negative for ferrous metals and positive for non-ferrous metals tall. As a result, at the output of the device for comparing relative amplitudes 10, regardless of the degree of mineralization of the soil, a signal of negative or positive polarity arrives at the input of the metal type indicator 11, which displays the presence of an object made of ferrous or non-ferrous metal.

The claimed design of the amplitude-frequency metal detector as a result of introducing compensation for soil mineralization, as well as selectivity for ferrous and non-ferrous metals, provides a selective search for metals of a certain type, both in ordinary soils and in complex soils with increased mineralization, increases the sensitivity and reliability of detection of small metal objects, reduces the number of unproductive excavations and increases the speed of searches, and also allows you to use a metal detector, as in the floor environmental conditions, including under water, and in stationary conditions for the detection of foreign metal inclusions in technological processes.

Claims (1)

An amplitude-frequency metal detector comprising an inductive metal sensor, a sinusoidal voltage generator, an amplitude detector, a first low-pass filter and an amplitude deviation amplifier connected in series, a frequency detector, a second low-pass filter and a frequency deviation amplifier connected in series, characterized in that it further comprises an adder, a device for comparing relative amplitudes and an indicator of the type of metal, connected in series, and the input of the frequency detector under is connected to the output of the sinusoidal voltage generator, the first adder input is connected to the output of the amplitude deviation amplifier, the second adder input and the second input of the relative amplitude comparison device are connected together and connected to the output of the frequency deviation amplifier, the adder output is connected to the first input of the relative amplitude comparison device, the output of which connects to a metal type indicator.