METAL DETECTOR FOR BURIED AND ABANDONED CHEMICAL WEAPONS

Abstract

A metal detector for buried and abandoned chemical weapons is provided, comprising: a transmitting circuit to transmit a detection signal; a frequency selection unit electrically connected to the transmitting circuit and configured to regulate a frequency of the detection signal; a receiving circuit to receive a reflected signal returned from the substance detected; an analog-digital conversion unit electrically connected to the receiving circuit and configured to convert the reflected signal into a digital signal; and a control unit electrically connected to the analog-digital conversion unit. In the present disclosure, the frequency of the detection signal can be regulated by changing a current frequency of the transmitting circuit, so that several forms of iron compound can be detected, thereby increasing the detection accuracy of the ACWs.

Description

FIELD

The present disclosure relates to detection of materials, in particular to a metal detector for buried and abandoned chemical weapons.

BACKGROUND

Since the end of the Second World War, huge amount of Abandoned Chemical Weapons (hereinafter to be referred as ACWs) still present in many countries pose a grave threat to people's lives and health, as well as environmental security. The ACWs, such as a chemical shell, chemical aerial bomb, gas bomb, and toxic agent barrel, are usually in the form of canisters filled with highly toxic chemicals like mustard gas, lewisite, diphenylcyanoarsine, diphenylchlorarsine, phosgene, a-chloroacetophenone, benzyl bromide, and hydrocyanic acid. Now over 70 years have passed since the end of the Second World War, the ACWs have corroded, which may result in leakage of the highly toxic chemicals and hence endangering lives and the environment. Except for the high toxicity, wide distribution is another characteristic of the ACWs.

The ACWs were mainly buried underground (hereinafter to be referred as buried ACWs), such as in pits or caves. Buried depths of most of the ACWs are no more than 5 meters, for example, 0 to 2 meters for falling bombs and 2 meters to 5 meters for bombs hidden in caves or tunnel. However, the ACWs were also found in abandoned mines with a depth of 100 meters. ACWs have also been found under residential areas, forest regions, and mountain regions. Compared to underground pipelines, the buried depths of the ACWs are greater and thus the detection is more difficult.

Small target of detection is another characteristic of the ACWs. For example, calibers of chemical shells in the ACWs generally are 75 mm, 90 mm, 105 mm, and 150 mm, calibers of chemical aerial bombs in the ACWs generally are 100 mm, and 198 mm, calibers of gas bombs in the ACWs generally are 290 mm, 114 mm, and 50 mm, and calibers of toxic agent barrels in the ACWs generally are 470 mm, 400 mm, and 325 mm.

As mentioned above, the ACWs are continuously corroding, and materials of packaging housings of the ACWs have been transformed to rust from metal such as iron or steel. Therefore, conventional detectors used to discover chemical weapons by detecting metal are no longer appropriate.

SUMMARY

According to an aspect of the present disclosure, a metal detector for buried and abandoned chemical weapons includes a transmitting circuit to transmit a detection signal, a frequency selection unit electrically connected to the transmitting circuit and configured to regulate a frequency of the detection signal, a receiving circuit to receive a reflected signal returned from a substance detected, an analog-digital conversion unit electrically connected to the receiving circuit and configured to convert the reflected signal into a digital signal, and a control unit electrically connected to the analog-digital conversion unit.

In one embodiment, the frequency selection unit includes an operational amplifier, a first amplifying circuit comprising a resistor R4, wherein two ends of the resistor R4 are respectively electrically connected to an inverting input of the operational amplifier and an output of the operational amplifier, a resistor R1, wherein one end of the resistor R1 is grounded and the other end of the resistor R1 is electrically connected to the inverting input of the operational amplifier, and a frequency selection circuit including a variable capacitor C1 and a variable resistor R2, wherein one end of the variable capacitor C1 is electrically connected to one end of the variable resistor R2 and grounded, and the other end of variable capacitor C1 and the other end of the variable resistor R2 are electrically connected to a non-inverting input of the operational amplifier, and a variable capacitor C2 and a variable resistor R3 which are electrically connected in series between the inverting input of the operational amplifier and the output of the operational amplifier.

In one embodiment, the frequency selection unit further includes a stabilivolt Dz to control an amplitude of a feedback voltage of the operational amplifier, and the stabilivolt Dz is electrically connected between the inverting input of the operational amplifier and the output of the operational amplifier.

In one embodiment, the metal detector further includes a second amplifying circuit electrically connected between the frequency selection unit and the transmitting circuit, wherein the second amplifying circuit includes a first step-up transformer including a first primary coil electrically connected to the frequency selection unit, and a first secondary coil and a second secondary coil which are electrically connected in series, a second step-up transformer comprising a second primary coil and a third primary coil which are electrically connected in series, and a third secondary coil, a first transistor, wherein one end of the first secondary coil is electrically connected to a base of the first transistor, the other end of the first secondary coil is grounded, an emitter of the first transistor is grounded, a collector of the first transistor is electrically connected to one end of the second primary coil, and the other end of the second primary coil is electrically connected to a cathode of a power supply V1, and a second transistor, wherein one end of the second secondary coil is electrically connected to a base of the second transistor, the other end of the second secondary coil is grounded, an emitter of the second transistor is grounded, a collector of the second transistor is electrically connected to one end of the third primary coil, and the other end of the third primary coil is electrically connected to the cathode of the power supply V1.

In one embodiment, the transmitting circuit further includes a transmitting coil electrically connected to the third secondary coil.

In one embodiment, the receiving circuit further includes a receiving coil electrically connected to the analog-digital conversion unit.

In one embodiment, the receiving circuit further includes a third amplifying circuit electrically connected between the receiving coil and the analog-digital conversion unit.

In one embodiment, the metal detector further includes a human-machine interaction module comprising a display unit and an input unit which are respectively and electrically connected to the control unit.

In one embodiment, the metal detector further includes a power supply unit respectively and electrically connected to the control unit, the analog-digital conversion unit, and the frequency selection unit.

In one embodiment, the metal detector further includes a voltage stabilizing circuit electrically connected to an output of the power supply unit and further respectively electrically connected to the control unit, the analog-digital conversion unit, and the frequency selection unit, wherein the voltage stabilizing circuit includes a resistor R19 and a stabilivolt D1, wherein the resistor R19, the stabilivolt D1 and, the power supply unit are electrically connected in series, and the stabilivolt D1 is electrically connected in parallel with the control unit.

In the present disclosure, the frequency of the detection signal can be regulated by the frequency selection unit so that different iron compounds can be detected. By selecting rust as detection target on account of the serious corrosion of the packing housing of the ACWs, the ACWs buried underground can be found efficiently and accurately.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a system diagram of one embodiment of a metal detector for buried and abandoned chemical weapons.

FIG. 2 is a circuit diagram of one embodiment of a frequency selection unit.

FIG. 3 is a diagram of one embodiment of an amplifying circuit at a transmitting end of the metal detector.

FIG. 4 is a diagram of one embodiment of a voltage stabilizing circuit.

FIG. 5 is a schematic diagram of one embodiment of a digital signal processor.

FIG. 6 is a diagram of one embodiment of a reset circuit.

FIG. 7 is a diagram of one embodiment of a crystal oscillation circuit.

FIG. 8 is a schematic diagram of one embodiment of an external RAM.

DETAILED DESCRIPTION

For a clear understanding of the technical features, objects and effects of the present disclosure, specific embodiments of the present disclosure will now be described in detail with reference to the accompanying drawings. It is to be understood that the following description is merely exemplary embodiments of the present disclosure, and is not intended to limit the scope of the present disclosure.

Today, after a long time of bury, the canisters of the ACWs have been corroded by chemical and/or electrochemical reactions with their environment, which consequently changed the original chemical, mechanical, and physical performances of the canisters. For example, most of the canisters of the ACWs are made by iron, and the rusting of the iron, a well-known example of the corrosion, can enable the mechanical properties such as plasticity, strength, and tenacity of the housings to decrease significantly. In addition, because of different reaction mechanisms and reaction environments, the corrosion of the canisters can be classified into general corrosion, pitting corrosion, crevice corrosion, intergranular corrosion, and filiform corrosion.

General corrosion, also known as uniform corrosion, behaves as uniform thinning of the entire canister due to substantially the same rate of corrosion.

Pitting corrosion is a kind of extremely localized corrosion that leads to holes formed in the canister due to non-uniform density of the canister. The resultant holes are usually small and deep.

Crevice corrosion refers to corrosion occurring in confined spaces such as contact areas between parts of the canister and welds of the canister. A crevice with a width of 0.025 mm to 0.1 mm is more susceptible to corrosion because a concentration cell is more easily formed within the above width range. If the crevice is too narrow, substances causing the corrosion cannot enter the crevice. If the crevice is a little wider, the substances causing the corrosion would pass through the crevice.

The intergranular corrosion is a form of corrosion where the boundaries of crystallites of the material are more susceptible to corrosion than their interiors. The intergranular corrosion proceeds along the boundaries of grains in the metal or near the boundaries with the largest portion of the grain remaining unaffected, thereby forming a localized corrosion. The main reason causing the intergranular corrosion is that the texture and structure of the boundary is different from the inside of the grain and consequently their electrochemical properties are different. The intergranular corrosion can lead to significant decrease of the plasticity, the strength, and the tenacity of metal materials.

The filiform corrosion is a thread-like type of corrosion which develops under protective coatings on the metal of canisters. When salt compound, such as chloride, is contained in the protective coating, water can be absorbed by the protective coatings and then penetrate the protective coatings to form droplets. Because the droplet contains more oxygen at its edge region than center region, galvanic corrosion is created between the edge region and the center region driven by a differential aeration cell. Consequently, hydroxyl ions are generated at the edge region, which decreases the surface tension of the droplet and facilitates the flow of the droplet, thereby forming the filiform corrosion.

Due to the corrosion, the iron contained in the canisters has been converted to rust. Components of the rust are complicated and can vary under different circumstances, mainly including Fe₂O₃.H₂O, FeOOH, FeO.H₂O, Fe(OH)₂, and Fe₃O₄.xH₂O. In the present disclosure, a detector metal 10 is provided to detect the buried ACWs by detecting ferromagnetic substance such as ferric oxide and ferroferric oxide. Magnetized ferric oxide and magnetized ferroferric oxide are less magnetic than magnetized iron. In the present disclosure, a transmitting frequency of the metal detector 10 can be in a range from about 20 kHz to about 80 kHz.

According to Lenz's law, when a conductor moves cutting magnetic induction lines, eddy current is produced inside the conductor, and a direction of the magnetic field generated by the eddy current is opposite to a direction of the magnetic field generated by an original transmitting circuit, so that a current intensity and a current phase of the transmitting circuit are changed, which further affects an equivalent impedance of a receiving circuit. The equivalent impedance can be further resolved into an equivalent resistor and an equivalent inductance. When the conductor is passing through the transmitting magnetic field, the equivalent resistor of the receiving circuit is increased and the equivalent inductance of the receiving circuit is changed according to a magnetism of the conductor. More specifically, if the conductor is magnetic, the receiving circuit is increased, and if the conductor is non-magnetic, the receiving circuit is decreased. In addition, substances with different permeabilities will have different magnetic phases. It is found that as a substance goes deeper underground, the magnetic phase of the substance is not obviously changed, meanwhile, the magnetic phase of the substance is also not changed with the size and orientation of the substance. Therefore, a kind of the substance can be determined by detecting and calculating the phase of the equivalent impedance, while the depth of the substance buried and the size of the substance can be determined by detecting and calculating the amplitude of the equivalent impedance.

With regard to the metal detector 10, the detection performance is affected by a current frequency of the transmitting circuit. More specifically, if the current frequency is relatively low, the electromagnetic wave transmitted would have better penetrability and thus could go deeper underground. However, it may fail to detect a small target. If the current frequency is relatively high, the small target would be detected successfully, but the detection range would not be wide. In addition, each substance corresponds to an optimum detection frequency, that is, the substance is more easily to be found at the optimum detection frequency. The optimum detection frequency is mainly affected by a ferromagnetism intensity of the substance detected. In general, iron corresponds to a relatively low optimum detection frequency and a ferromagnetic substance, such as rust, corresponds to a relatively high optimum detection frequency.

Referring to FIG. 1, one embodiment of the present disclosure provides the metal detector 10 for the buried ACWs. The metal detector 10 includes a frequency selection unit 100, a transmitting circuit 200, a receiving circuit 500, an analog-digital conversion unit 400, and a control unit 300. The transmitting circuit 200 is configured to transmit a detection signal. The frequency selection unit 100 can be electrically connected to the transmitting circuit 200 and is configured to regulate a frequency of the detection signal. The receiving circuit 500 is configured to receive reflected signals returned from a substance detected. The analog-digital conversion unit 400 can be electrically connected to the receiving circuit 500 and is configured to convert the detection signal to a digital signal. The control unit 300 can be electrically connected to the analog-digital conversion unit 400 and is configured to process the digital signal received from the analog-digital conversion unit 400. The control unit 300 can be further used to control an operating state of the metal detector 10.

The frequency selection unit 100 can regulate the frequency of the detection signal by changing a current frequency of the transmitting circuit 200. Consequently, several forms of iron compound can be detected, thereby increasing the detection accuracy of the metal detector 10 to the ACWs.

Referring to FIG. 2, in one embodiment, the frequency selection unit 100 can further include an operational amplifier 110, a first amplifying circuit 120, and a frequency selection circuit 130. The first amplifying circuit 120 can include a resistor R4. Two ends of the resistor R4 can be respectively and electrically connected to an inverting input and an output of the operational amplifier 110. The first amplifying circuit 120 can further include a variable resistor R1. One end of the variable resistor R1 can be grounded, and the other end of the variable resistor R1 can be electrically connected to the inverting input of the operational amplifier 110.

The frequency selection circuit 130 can include a variable capacitor C1, a variable resistor R2, a variable capacitor C2, and a variable resistor R3. One end of the variable capacitor C1 and one end of the variable resistor R2 can be electrically connected to each other and grounded. The other end of the variable capacitor C1 and the other end of the variable resistor R2 can be respectively and electrically connected to a non-inverting input of the operational amplifier 110. The variable capacitor C2 and the variable resistor R3 can be electrically connected in series with each other between the inverting input of the operational amplifier 110 and the output of the operational amplifier 110. The frequency selection circuit 130 is configured to change the frequency of the detection signal. The first amplifying circuit 120 and the frequency selection circuit 130 cooperate to perform amplification by using positive feedback mechanism, wherein a feedback factor F is equal to a ratio of a voltage of the non-inverting input of the operational amplifier 110 to a voltage of the output of the operational amplifier 110. More specifically, the feedback factor F can be calculated by the following equation:

$F=\frac{k*k}{k*k+2+j\left(\mathrm{wRC}-\frac{1}{\mathrm{wRC}}\right)},$

wherein k is a real number, R=R2=R3, and C=C1=C2. As can be seen from the above equation, if

$\frac{1}{\mathrm{wC}}>R\mathrm{or}\frac{1}{\mathrm{wC}}<R,$

and an amplification factor of the first amplifying circuit 120 is slightly more than (k*k+2)/(k*k), then a sinusoidal wave with a frequency satisfying

$f=\frac{1}{2\pi \mathrm{RC}}$

can be separated out. Moreover, since the amplification factor is less than 1, other frequency components will be attenuated to 0, consequently the sinusoidal wave can be obtained.

To ensure that the amplification factor of the first amplifying circuit 120 is slightly more than (k*k+2)/(k*k), and R4/R1 is required to be slightly more than 2. It can be seen from equation

$f=\frac{1}{2\pi \mathrm{RC}}$

that a frequency of the sinusoidal wave output from the frequency selection unit 100 can be regulated by changing values of R and C, namely by changing the values of the variable resistors R2 and R3 and/or the values of the variable capacitances C1 and C2. In one embodiment, by using a switch and variable capacitances having wide capacitance ranges, the frequency of the sinusoidal wave can be coarsely regulated. In addition, by using a digital potentiometer to adjust resistor values of variable resistors, the frequency of the sinusoidal wave can be finely regulated.

In one embodiment, the frequency selection unit 100 can further include a stabilivolt Dz configured to control an amplitude of a feedback voltage of the operational amplifier 110. The stabilivolt Dz can be electrically connected between the inverting input of the operational amplifier 110 and the output of the operational amplifier 110. Since the first amplifying circuit 120 performs amplification by using positive feedback mechanism, an output voltage should be limited such as by the stabilivolt Dz.

Referring to FIG. 3, in one embodiment, the metal detector 10 can further include a second amplifying circuit 600 electrically connected between the frequency selection unit 100 and the transmitting circuit 200. The second amplifying circuit 600 can include a first step-up transformer 650, a second step-up transformer 660, a first transistor 670, and a second transistor 680. The first step-up transformer 650 can include a first primary coil 610, a first secondary coil 611, and a second secondary coil 612. The first primary coil 610 can be electrically connected to the frequency selection unit 100. The first secondary coil 611 and the second secondary coil 612 can be electrically connected in series. The second step-up transformer 660 can include a second primary coil 620, a third primary coil 630, and a third secondary coil 631. The second primary coil 620 and the third primary coil 630 can be electrically connected in series. One end of the first secondary coil 611 can be electrically connected to a base of the first transistor 670 and the other end of the first secondary coil 611 can be grounded. An emitter of the first transistor 670 can be grounded. A collector of the first transistor 670 can be electrically connected to one end of the second original coil 620, and the other end of the second original coil 620 can be electrically connected to a cathode of a power source V1. One end of the second secondary coil 612 can be electrically connected to a base of the second transistor 680, and the other end of the second secondary coil 612 can be grounded. An emitter of the second transistor 680 can be grounded. A collector of the second transistor 680 can be electrically connected to one end of the third primary coil 630, and the other end of the third primary coil 630 can be electrically connected to an anode of the power supply V1. The second amplifying circuit 600 can be a push-pull amplifying circuit. In one embodiment, the signal input from the frequency selection unit 100 to the first step-up transformer 650 is such that when the polarity of the voltage of the first step-up transformer 650 is positive/negative, the first transistor 670 is turned on and the second transistor 680 is turned off, when the polarity of the voltage of the first step-up transformer 650 is negative/positive, the first transistor 670 is turned off and the second transistor 680 is turned on.

The first step-up transformer 650 is configured to increase the voltage output by the frequency selection unit 100. The second step-up transformer 660 is configured to increase the primary equivalent resistor of the load to improve the power consumption efficiency and reduce the power loss caused by the small resistor of the transmitting coil.

In one embodiment, the transmitting circuit 200 can further include a transmitting coil. The transmitting coil can be electrically connected to the third secondary coil 631.

In one embodiment, the receiving circuit can further include a receiving coil for receiving signal. The transmitting coil and the receiving coil can be independently made by metal materials. A shape of the transmitting coil or the receiving coil is not limited, such as a rectangle or a circle, as long as it is convenient to transmit or receive signal. In one embodiment, shapes of the transmitting coil and the receiving coil can be respectively a rectangle with a size of 40 cm×120 cm. The transmitting coil and the receiving coil both can be made of copper. In one embodiment, the transmitting coil and the receiving coil are located in the same plane and spaced from each other, which reduces mutual interference between the two coils. An insulating material can be wrapped on a surface of a wire electrically connected to the transmitting coil and/or the receiving coil to protect the transmitting coil and/or the receiving coil.

In one embodiment, the receiving circuit can further include a third amplifying circuit. The third amplifying circuit can be electrically connected between the receiving coil and the analog-digital conversion unit 400. The third amplifying circuit is configured to amplify the received signal. In one embodiment, the third amplifying circuit can have the same structure as the second amplifying circuit 600 and details will not be described herein again.

In one embodiment, the metal detector 10 can further include a human-machine interaction module 700. The human-machine interaction module 700 can include a display unit 710 and an input unit 720. The display unit 710 and the input unit 720 can be respectively and electrically connected to the control unit 300. The display unit 710 is configured to display a detection result. The display unit 710 can include a liquid crystal display. The detection result displayed can include a kind and an orientation of the substance detected. In addition, information such as a current transmitting frequency and a frequency and a phase of the received signal can further be displayed by the display unit 710. In one embodiment, the liquid crystal display is a 128×64 dot matrix liquid crystal display (LCD 12864). The LCD 12864 is easy to use and inexpensive and has a simpler circuit structure and software program design compared to other dot matrix display module. The specific parameters of the LCD 12864 are listed as follows.

1	power supply voltage	3.3 V
2	display resolution	128 × 64
3	built-in font file	providing 8192 bitmap fonts
4	built-in 128 16×8 dot characters
5	clock frequency	2 MHz
6	display mode	STN, transflective, positive
7	driving method	1/33 DUTY, 1/6 BIAS
8	viewing direction	6 o'clock
9	communication mode	optionally, serial prot, parallel port
10	built-in DC-DC switching circuit without additional negative voltage
11	without chip selection signal, simplified software design
12	operating temperature	0° C. to 55° C.
13	storage temperature	−20° C. to 60° C.

Pins of the LCD 12864 are listed as follows.

PIN NO.	SYMBOL	DESCRIPTION
1	VSS	ground
2	VCC	power supply	electrically connected to +3.3 V
3	V0	negative terminal of
		contrast adjustment
4	RS	control signal	RS = 0 indicates that instruction data is on data
			line, and RS = 1 indicates that display data is on
			data line.
5	R/W	read/write control	data line is readable at high level, data line is
		signal	written at low level
6	E	Enable signal	performing read-write of data line cooperating
			with R/W
7~14	three-state data line
15	PSB	serial/parallel	serial at low level and parallel at high level
		selection
16	NC	not connected
17	/RESET	reset terminal	active LOW
18	VOUT	positive terminal of
		contrast adjustment
19	LED_A	positive terminal of	electrically connected to +3.3 V
		back light
20	LED_K	positive terminal of	ground
		back light

The input unit 720 can include a keyboard. Data and control instruction can be input by the keyboard. The keyboard can include a plurality of keys to control a plurality of switches. Each of the plurality of switches or any combination thereof can be used to realize a specified function. In one embodiment, the keyboard is an independent connection type of keyboard, more specifically, each of the plurality of keys acts as an independent input to data line. In one embodiment, an operating mode of the metal detector 10 can be regulated by the keyboard. For example, the detection frequency of the metal detector 10 can be switched among several frequency ranges and/or continuously switched within one frequency range.

In one embodiment, the metal detector 10 can further include a power supply unit 800. The power supply unit 800 can be electrically connected to the control unit 300, the analog-digital conversion unit 400, and the frequency selection unit 100 respectively.

In one embodiment, the power supply unit 800 can be a DC power supply V1, such as a CA100FI battery produced by CHINA AVIATION LITHIUM BATTERY CO., LTD. In one embodiment, a power supply voltage of the DC power supply V1 is about 3.2 V, which can meet the power supply requirement of the control unit 300. In one embodiment, the DC power supply V1 can directly provide direct current for the frequency selection unit 100, the display unit 710, and the input unit 720. In one embodiment, to power the operational amplifier 110 in the frequency selection unit 100, an output voltage of the CA100FI battery can be boosted to and stabilized at 12 V by AS1345D chip. In one embodiment, to power the analog-digital conversion unit 400, the output voltage of the CA100FI battery can be firstly boosted to and stabilized at 5.25 V by AS1345D chip and then reduced to 5 V by AS1335 chip. In one embodiment, to power the control unit 300, the output voltage of the CA100FI battery can be firstly boosted to and stabilized at 5.25 V by AS1345D chip and then reduced to 3.3 V by AS1335 chip.

Referring to FIG. 4, in one embodiment, an output of the power supply unit 800 can be electrically connected to a voltage stabilizing circuit 810. The voltage stabilizing circuit 810 can be further electrically connected to the control unit 300, the analog-digital conversion unit 400, and the frequency selection unit 100 respectively. The voltage stabilizing circuit 810 can include a resistor R19 and a stabilivolt D1 electrically connected in series with each other and the power supply unit 800. The stabilivolt D1 can be further electrically connected in parallel with the control unit 300. The voltage stabilizing circuit 810 is configured to ensure stability of the voltage input to the control unit 300, the analog-digital conversion unit 400, and the frequency selection unit 100.

Referring to FIG. 5 to FIG. 7, in one embodiment, the control unit 300 can include a digital signal processor and a reset circuit 950. A VCC interface of the reset circuit 950 can be electrically connected to a power supply. A RESET interface of the reset circuit 950 can be electrically connected to the digital signal processor. The control unit 300 can further include a crystal oscillator circuit 960. An interval of a counter can be set by the crystal oscillator circuit 960. The crystal oscillation circuit 960 can include a capacitor C11, a capacitor C12, and a crystal oscillator X1 which are sequentially electrically connected in series. A wire connecting the capacitor C11 to the capacitor C12 of the crystal oscillation circuit 960 can be grounded.

Referring to FIG. 8, in one embodiment, the control unit 300 can further includes an external RAM. The RAM can be CY7C1019. The RAM can be electrically connected to the digital signal processor.

In one embodiment, the analog-digital conversion unit 400 can include an AD7858 chip with 8 input channels and a sampling frequency of up to 200 kHz. The digital signal processor can be provided with DC2289 through SPI serial port. The DC2289 is a 24 bit chip with a sampling frequency of 1 MHz which is 10 times larger than 80 kHz, and the waveform of the received signal can be well described. The AD7858 has one control register, one ADC data output register, one status register, one test register, and ten calibration registers. In order to avoid spectral aliasing that occurs after FFT (Fast Fourier Transform), the sampling frequency of the AD7858 chip should be higher than twice of the highest frequency of 80 kHz.

In one embodiment, the received signal is converted by the analog-digital conversion unit 400 to a digitized received signal. Due to the complicated environment, the received signal is not a sinusoidal wave with one frequency, but a signal mixed by different frequencies. Therefore, it is necessary to convert the signal to the frequency domain for frequency analysis to find the main part of the frequency. After receiving the time domain discrete signal converted by the analog-digital conversion unit 400, the FFT is used to convert the signal to the frequency domain. Since the previous analog-digital conversion has a sufficiently high sampling frequency, there will be no aliasing caused by the FFT.

Assuming that the transmitting frequency is f, a data length processed by the FFT is 1, and the sampling frequency is F, then a position of a sample dot of discrete Fourier transform (DFT) n corresponding to the transmitting frequency can satisfy the following equation:

nF=lf

The transmitting signal and the received signal can be respectively analyzed by FFT to obtain digital information of dominant frequencies thereof, and the difference of the phases therebetween and the difference of the amplitudes therebetween can be determined. The kind, size, and orientation of the substance detected can be obtained according to the amplitude information and the phase information.

It will be understood that when an element is referred to as being “connected” or “coupled” to another element, it can be directly connected or coupled to the other element or intervening elements may be present. In contrast, if an element is referred to as being “directly connected” or “directly coupled” to another element, there are no intervening elements present. The terms “vertical”, “horizontal”, “left” and “right” and other similar expressions used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

Finally, it is to be understood that the above-described embodiments are intended to illustrate rather than limit the present disclosure. Variations may be made to the embodiments without departing from the spirit of the present disclosure as claimed. Elements associated with any of the above embodiments are envisioned to be associated with any other embodiments. The above-described embodiments illustrate the scope of the present disclosure but do not restrict the scope of the present disclosure.

Claims

1. A metal detector for buried and abandoned chemical weapons, comprising: a transmitting circuit configured to transmit a detection signal;a frequency selection unit electrically connected to the transmitting circuit and configured to regulate a frequency of the detection signal;a receiving circuit configured to receive a reflected signal returned from the substance detected;an analog-digital conversion unit electrically connected to the receiving circuit and configured to convert the reflected signal into a digital signal; anda control unit electrically connected to the analog-digital conversion unit.

2. The metal detector of claim 1, wherein the frequency selection unit comprises: an operational amplifier;a first amplifying circuit comprising: a resistor R4, two ends of the resistor R4 being respectively and electrically connected to an inverting input of the operational amplifier and an output of the operational amplifier;a resistor R1, one end of the resistor R1 being grounded and the other end of the resistor R1 being electrically connected to the inverting input of the operational amplifier; anda frequency selection circuit comprising: a variable capacitor C1 and a variable resistor R2, one end of the variable capacitor C1 being electrically connected to one end of the variable resistor R2 and grounded, and the other end of variable capacitor C1 and the other end of the variable resistor R2 being electrically connected to a non-inverting input of the operational amplifier;a variable capacitor C2 and a variable resistor R3 being electrically connected in series between the inverting input of the operational amplifier and the output of the operational amplifier.

3. The metal detector of claim 1, wherein the frequency selection unit further comprises a stabilivolt Dz configured to control an amplitude of a feedback voltage of the operational amplifier, the stabilivolt Dz is electrically connected between the inverting input of the operational amplifier and the output of the operational amplifier.

4. The metal detector of claim 1, further comprising a second amplifying circuit electrically connected between the frequency selection unit and the transmitting circuit, wherein the second amplifying circuit comprises: a first step-up transformer comprising: a first primary coil electrically connected to the frequency selection unit;a first secondary coil and a second secondary coil being electrically connected in series;a second step-up transformer comprising: a second primary coil and a third primary coil being electrically connected in series;a third secondary coil;a first transistor, one end of the first secondary coil being electrically connected to a base of the first transistor, the other end of the first secondary coil being grounded, an emitter of the first transistor being grounded, a collector of the first transistor being electrically connected to one end of the second primary coil, and the other end of the second primary coil being electrically connected to a cathode of a power supply V1; anda second transistor, one end of the second secondary coil being electrically connected to a base of the second transistor, the other end of the second secondary coil being grounded, an emitter of the second transistor being grounded, a collector of the second transistor being electrically connected to one end of the third primary coil, and the other end of the third primary coil is electrically connected to the cathode of the power supply V1.

5. The metal detector of claim 4, wherein the transmitting circuit further comprises a transmitting coil electrically connected to the third secondary coil.

6. The metal detector of claim 1, wherein the receiving circuit further comprises a receiving coil electrically connected to the analog-digital conversion unit.

7. The metal detector of claim 1, wherein the receiving circuit further comprises a third amplifying circuit electrically connected between the receiving coil and the analog-digital conversion unit.

8. The metal detector of claim 1, further comprising: a human-machine interaction module comprising a display unit and an input unit respectively and electrically connected to the control unit.

9. The metal detector of claim 1, further comprising: a power supply unit respectively and electrically connected to the control unit, the analog-digital conversion unit, and the frequency selection unit.

10. The metal detector of claim 1, further comprising: a voltage stabilizing circuit electrically connected to an output of the power supply unit and further respectively and electrically connected to the control unit, the analog-digital conversion unit, and the frequency selection unit, wherein the voltage stabilizing circuit comprises: a resistor R19 and a stabilivolt D1, the resistor R19, the stabilivolt D1, and the power supply unit being electrically connected in series, and the stabilivolt D1 being electrically connected in parallel with the control unit.

11. The metal detector of claim 1, wherein the frequency selection unit is configured to regulate the frequency of the detection signal within a range from about 20 kHz to about 80 kHz.

12. The metal detector of claim 1, wherein the frequency selection unit is configured to regulate the frequency of the detection signal corresponding to an optimal detection frequency of at least one of Fe2O3, FeOOH, FeO, Fe(OH)2, and Fe3O4.

13. The metal detector of claim 2, wherein a ratio of a resistor value of the resistor R4 to a resistor value of the resistor R1 is slightly more than 2.

14. The metal detector of claim 1, wherein the analog-digital conversion unit has a sampling frequency of more than 160 kHz.

15. A metal detector for buried and abandoned chemical weapons, comprising: a transmitting circuit configured to transmit a detection signal;a frequency selection unit electrically connected to the transmitting circuit and configured to regulate a frequency of the detection signal;a receiving circuit configured to receive a reflected signal returned from the substance detected;a signal processing unit electrically connected to the receiving circuit and configured to acquire phases of the reflected signal and the detection signal and amplitudes of the reflected signal and the detection signal.

16. The metal detector of claim 15, wherein the frequency selection unit comprises: an operational amplifier;a first amplifying circuit comprising: a resistor R4, two ends of the resistor R4 being respectively and electrically connected to an inverting input of the operational amplifier and an output of the operational amplifier;a resistor R1, one end of the resistor R1 being grounded and the other end of the resistor R1 being electrically connected to the inverting input of the operational amplifier; anda frequency selection circuit comprising: a variable capacitor C1 and a variable resistor R2, one end of the variable capacitor C1 being electrically connected to one end of the variable resistor R2 and grounded, and the other end of variable capacitor C1 and the other end of the variable resistor R2 being electrically connected to a non-inverting input of the operational amplifier;a variable capacitor C2 and a variable resistor R3 being electrically connected in series between the inverting input of the operational amplifier and the output of the operational amplifier.

17. The metal detector of claim 16, wherein the frequency selection unit further comprises a stabilivolt Dz configured to control an amplitude of a feedback voltage of the operational amplifier, the stabilivolt Dz is electrically connected between the inverting input of the operational amplifier and the output of the operational amplifier.

18. The metal detector of claim 16, wherein the frequency selection circuit is configured to regulate the frequency of the detection signal within a range from about 20 kHz to about 80 kHz by regulating values of the variable capacitor C1, the variable resistor R2, the variable capacitor C2, and the variable resistor R3.

19. The metal detector of claim 16, wherein a ratio of a resistor value of the resistor R4 to a resistor value of the resistor R1 is slightly more than 2.

20. The metal detector of claim 1, wherein the signal processing unit is an analog-digital conversion unit.