KR101619491B1 - Metal detecting apparatus generating variable frequency according to digital switching - Google Patents

Abstract

The present invention relates to a metal detector, and more particularly, to a metal detector for detecting a metal remaining in a food, wherein the frequency oscillated by the transmitter is oscillated by a digital control.
A variable frequency oscillating metal detector according to the present invention includes a transmitter for amplifying an oscillation frequency and scanning a signal to be inspected through a transmission antenna to a food to be inspected, Wherein the oscillation frequency is oscillated by a variable sinusoidal oscillator in which an inductance and two or more capacitances are connected in parallel and the input of each of the capacitors is oscillated by a digital controller Off-switching, and the variable sinusoidal oscillator oscillates different frequencies by on-off control of the digital controller.

Description

TECHNICAL FIELD [0001] The present invention relates to a variable frequency oscillating metal detector for digital switching,

The present invention relates to a metal detector, and more particularly, to a metal detector for detecting a metal remaining in a food, wherein the frequency oscillated by the transmitter is oscillated by a digital control.

Since the optimum frequency to be used differs depending on the type of food to be inspected, the metal detection device used in the conventional food inspection needs to change the frequency used for metal detection There is a disadvantage that different transmission antennas must be used.

Methods for detecting the presence or absence of metal objects in food of different kinds can be roughly divided into three methods.

In the first method, a frequency is varied by using one transmission antenna. In this method, for example, when the frequency used is increased by a factor of 10, the impedance of the transmission antenna is increased by about 10 times, and the actual transmission power is reduced to about 1/10, so that the variable frequency width can not be increased.

In the second method, a separate transmission antenna is installed according to the frequency band used for metal detection. This method has a disadvantage that the structure is complicated and the cost is increased.

In the third method, a plurality of fixed transmission frequency signals are mathematically summed and transmitted using one transmission antenna. Also in this case, since the transmission antenna exhibits the optimum impedance characteristic only at a specific frequency, there is a disadvantage that a problem similar to the first method is caused.

In order to solve such a conventional problem, Korean Patent Registration No. 10-1019100 discloses an apparatus and method for detecting a metal object in a food.

Korean Patent Registration No. 10-1019100 is filed and registered by the present applicant. The metal detector includes an f1 frequency oscillator that oscillates a relatively high sinusoidal frequency in a transmitter, an f2 frequency oscillator that oscillates a relatively low sinusoidal frequency, And a power amplifier for amplifying the modulated signal. The signal amplifier amplifies the modulated signal received by the receiver coil through the food to be inspected in the receiver, and separates the amplified signal into two signals And a frequency synchronization detector for separating the two transmitted original frequency components so that the transmission efficiency of two transmission frequency bands can be reduced without decreasing the transmission efficiency by using one transmission antenna, A plurality of kinds of metal objects in the inspection target food having different optimum frequency bands are detected It is providing device.

However, the metal detector disclosed in Korean Patent Publication No. 10-1019100 is only capable of selectively using only two different frequencies, which is insufficient to actively perform various frequency oscillations for various foods.

In the manufacturing stage, a cone sensor is connected in parallel with a transmission antenna, and a current value is measured to find a capacitor value that consumes the least amount of current. Generally, one or more capacitors are combined in parallel to find a resonance value do. However, since the capacitor is mass-produced at the E6 or E12 series, there is a problem that a plurality of capacitors must be assembled to induce accurate resonance.

Korean Patent Publication No. 10-1019100

SUMMARY OF THE INVENTION A problem to be solved by the present invention is to provide a metal detector capable of oscillating by selecting a frequency corresponding to various foods by providing a digital variable oscillator capable of oscillating a variable frequency in one metal detector I want to.

The present invention also provides a digital variable frequency oscillator capable of generating 2n frequencies according to digital switching of variable frequency oscillation and oscillating to freely select a frequency for various foods.

According to an aspect of the present invention, there is provided a variable frequency oscillating metal detector for digital switching, comprising: a transmitter for amplifying an oscillation frequency and scanning a target food through a transmission antenna; The oscillation frequency being oscillated by a variable sinusoidal oscillator in which inductance and two or more capacitances are connected in parallel, and the oscillation frequency of each of the capacitors The input is switched on and off by a digital controller, and the variable sinusoidal oscillator oscillates different frequencies by on-off control of the digital controller.

Here, it is preferable that the inductance and the two or more capacitance values are preset so that the oscillation frequency can oscillate in the range of 50 kHz to 1 MHz.

이고, 여기서, f는 발진주파수, L은 인덕턴스, Cs는 병렬연결된 캐패시터 중 스위치가 온된 라인의 캐패시터의 합성 캐패시터이며, 2ⁿ(n는 2 이상의 정수)개의 정형파 주파수를 발진시키는 것을 특징으로 하여 이루어진다.Here, when the capacitance of the sinusoidal oscillator is C1, C2, C3, ... , Cn are in parallel, the oscillation frequency is

, Where f is an oscillation frequency, L is an inductance, Cs is a composite capacitor of a capacitor of a switched-on capacitor among the capacitors connected in parallel, and oscillates ²ⁿ (n is an integer of 2 or more) square wave frequencies .

Here, the variable sinusoidal frequency oscillated by the variable sinusoidal oscillator is amplified by a power amplifier, and the amplified frequency is transmitted to a transmission antenna through a consumption current detector, and the consumption current detector measures a current flowing to the transmission antenna And the sinusoidal frequency at which the consumed current becomes the smallest can be selected so that the optimum resonance condition can be formed.

According to the above-described configuration of the present invention, it is possible to provide a digital variable oscillator capable of oscillating a variable frequency in one metal detector, to select oscillation frequencies corresponding to various foods, It is possible to provide a digital variable frequency oscillation device capable of freely performing frequency selection according to various foods by generating and oscillating the frequency of the digital variable frequency oscillation device.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a coil layout diagram of a detachable sensor unit of a metal detector according to the present invention; FIG.
2 is a coil layout of a closed sensor part of a metal detector according to the present invention.
3 is a signal processing block diagram of a metal detector according to the present invention.
4 is a circuit diagram of a digital frequency oscillator of a metal detector according to the present invention.

Hereinafter, a circuit structure and operation effects of a variable frequency oscillating metal detector according to the present invention will be described with reference to the accompanying drawings.

FIG. 1 is a coil arrangement diagram of a detachable sensor unit of a metal detector according to the present invention, and FIG. 2 is a coil arrangement diagram of a closed sensor unit of a metal detector according to the present invention.

1 schematically shows a detachable sensor unit 11 configured to be separated into a signal transmitting unit and a signal receiving unit of a metal detecting device for inspecting the presence or absence of a metallic object, which is a foreign object, while the food to be inspected moves in the traveling direction.

A transmitter 12 for applying a sinusoidal frequency is connected to the transmission coil 13 having a rectangular outline and a receiver coil 15 for receiving the received signal at the originally transmitted transmission frequency is connected to the loop- Respectively.

FIG. 2 schematically shows a sensor unit 21 in which the transmitting and receiving antenna coils are integrally closed in a manner different from that shown in FIG.

The food to be inspected moves into the signal transmitting and receiving unit of the closed type sensor unit 21 in the traveling direction in order to check whether or not the metal body exists.

The closed metal detecting device sensor unit 21 includes a closed metal detector transmitter 22 connected to the transmitting coil 23 and applying a sinusoidal frequency to the receiving coil 24, And a receiver (25) for receiving the data.

3 is a signal processing block diagram of a metal detector according to the present invention.

3, the metal detector according to the present invention includes a digital controller 31, a transmitter 32, and a receiver 33. As shown in FIG.

The digital controller 31 turns on and off each oscillation circuit of the transmitter 32 through on / off of each switch to digitally control the oscillation circuit.

The transmission unit 32 amplifies the frequency generated by the variable sinusoidal oscillator 321 to a proper signal power in the power amplifier 322, and then applies the amplified signal to the transmission antenna 324 for scanning.

Here, a consumption current detector 323 is placed between the power amplifier 322 and the transmission antenna 324.

The consumption current detector 323 includes a circuit for converting a current into a voltage so as to measure the current flowing to the transmission antenna 324 and outputs the voltage measured by the consumption current detector 323 to the analog digital signal converter 325, And then monitored by a computer 336. [

When the frequency of the variable sinusoidal oscillator 321 is varied by monitoring the consumption current detector 323 and the computer 336, the frequency at which the current becomes the smallest can be found, which becomes the parallel resonance point.

It is possible to make the resonance condition more accurate than when finding the resonance point by fixing the frequency and using a combination of capacitors as in the conventional case.

This is because as the resonance becomes more accurate, the frequency selectivity of the antenna becomes better, so that it is possible to detect a change in a smaller signal, thereby improving the performance of the metal detector.

The linearly scanned foreign matter metal object detecting device receiving section 33 amplifies a signal received by the receiving antenna 331 through a part of the food to be inspected by the signal amplifier 332 up to a size required for signal processing, And the noise component is removed from the filter 333.

In order to separate the transmitted original signal frequency component, a variable sinusoidal oscillator 321 receives a synchronization signal and obtains an output signal proportional to the signal strength received by the reception antenna 331 at the synchronization detector 334.

That is, the output signal from the receiving antenna 331 is expressed as an analog waveform with respect to time in the signal synchronous detector 334, and the analog waveform is scanned while linearly moving the transmitting / receiving antenna by the supporting frame. The signal output is proportional to the size of the metal object present in the food to be inspected in the form of almost no output, but the maximum value when passing over a metal object and decreasing after passing through the metal object.

The output signal of the signal synchronization detector is converted into a digital waveform by the analog digital signal converter 335 so that it can be processed by the computer 336 and then inputted to the computer 336. [

The computer 336 processes the program in accordance with a pre-programmed manner and outputs an output signal to the output unit 338 for determining the presence or absence of the metal object, and displays the position and the shape of the metal object in the food to be inspected on the two-dimensional display 337.

4 is a circuit diagram of a digital frequency oscillator of a metal detector according to the present invention.

The variable sinusoidal oscillator 32 shown in FIG. 4 has a circuit structure in which an inductance L and two or more capacitances C are connected in parallel.

More than two capacitances C are connected to a relay that can be switched, respectively, and each of the relays is connected to a digital controller 31 for transmitting and controlling the signals.

In FIG. 4, the four capacitors C1 to C4 have a parallel connection structure. However, if two or more capacitors are connected in parallel, any form of the problem is not a problem.

Each of the capacitance (C1 to C4) are turned on by each of the digital controller (31) to thereby vary the output frequency (f _out) by increasing the opening or closing off the circuit.

The output frequency f _out can be output as 2 ⁿ (n is an integer of 2 or more) depending on the number of capacitances.

In other words, when two capacitances are connected in parallel, four variable frequencies of 2 ² can be output. When three capacitances are connected in parallel, eight variable frequencies of 2 ³ can be outputted. When four capacitances are connected in parallel, ^Four 16 variable frequencies can be output, and when five capacitances are connected in parallel, 32 variable frequencies of 2 ⁵ can be output.

Digital controller 31 is four relays (Relay1 to Relay4) can be either on all or off, and one of only either one relay or by increasing one of the two relays, or on the three relays ²⁴ of frequency synthesis . ≪ / RTI >

이고, Relay1과 Relay2가 온인 경우 발진주파수는

이며, Relay1, Relay2, Relay3가 온인 경우 발진주파수는

이고, Relay1, Relay2, Relay3, Relay4 모두 온인 경우 발진주파수는

이 되어, 2⁴ 개의 가변주파수를 만들 수 있게 된다.That is, when only the relay (Relay1) is on, the oscillation frequency

, And when Relay1 and Relay2 are on, the oscillation frequency is

, And when Relay1, Relay2, and Relay3 are on, the oscillation frequency is

And Relay1, Relay2, Relay3, and Relay4 are all on, the oscillation frequency is

So that it is possible to generate 2 ⁴ variable frequencies.

The inductance and the capacitance value are calculated in advance so that the frequency used as the metal detector in the food can be oscillated. Generally, the oscillation frequency is set within the range of 50 KHz to 1 MHz and the oscillation frequency can be 2n The inductance and the capacitance value of two or more are determined.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, As will be understood by those skilled in the art. Therefore, it should be understood that the above-described embodiments are to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than the foregoing description, It is intended that all changes and modifications derived from the equivalent concept be included within the scope of the present invention.

11: Detachable sensor unit 12, 22: Transmitter
13, 23: transmitting coil 14, 24: receiving coil
15, 25: Receiver 21: Closed sensor part
31: Digital controller 32: Transmitter
33: Receiving unit 321: Variable sinusoidal oscillator
322: Power amplifier 323: Current consumption detector
324 transmit antenna 325 335 analog digital signal converter
331: Receive antenna 332: Amplifier
333: frequency band pass filter 334: synchronous detector
336: Computer 337: Two-dimensional display
338: Output section

Claims (4)

A transmitter for amplifying an oscillation frequency and scanning a target food through a transmission antenna; a receiver for transmitting a food to be inspected and amplifying a signal received by the receiver antenna into a digital signal and outputting the amplified signal; In this case,
The oscillation frequency is oscillated by a variable sinusoidal oscillator in which inductance and two or more capacitances are connected in parallel,
The input of each of the capacitances is on-off switched by a digital controller,
Wherein said variable sinusoidal oscillator oscillates different frequencies by on-off control of said digital controller,
Wherein the oscillation frequency is amplified and transmitted to a consumption current detector, and a sinusoidal frequency is selected according to a current value measured from the consumption current detector. The method according to claim 1,
Wherein the inductance and the at least two capacitance values are preset so that the oscillation frequency can be oscillated in the range of 50 kHz to 1 MHz. The method according to claim 1,
The capacitance of the variable sinusoidal oscillator is C1, C2, C3, ... , Cn are arranged in parallel,
The oscillation frequency is

ego,
Here, f is an oscillation frequency, L is an inductance, and Cs is a composite capacitor of a capacitor of a switched-on capacitor among the capacitors connected in parallel,
2 ⁿ (where n is an integer equal to or greater than 2) number of variable-shaped waveform frequencies. The method according to claim 1,
The variable sinusoidal frequency oscillated by the variable sinusoidal oscillator is transmitted to the transmission antenna through the consumption current detector,
Wherein the consumption current detector assists in selecting a sinusoidal frequency when the consumption current is the smallest.

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