JPH0587943A - Magnetic sensor - Google Patents

Abstract

PURPOSE:To improve a gain of a high frequency component easily and at a low cost by connecting a capacitor for resonance in parallel with one of receiving coils on one side of an input resistance of an amplifier which amplifies signals entering the receiving coils. CONSTITUTION:For example, a coin path 71 is provided between a transmitting coil 20 and a receiving coil 30 and a coil 70 rolls in the coil path 71 to amplify a signal entering the receiving coil 30 allowing the detection of the coil 70. The transmitting coil 20 feeds a current having a specified frequency and the receiving coil 30 receives a signal from the transmitting coil 20. A differential amplification circuit 40 amplified a signal generated at both ends of the receiving coil 30 and has an input resistance R1 to a (-) input terminal of a differential amplifier DA, an input resistance R2 to a (+) input terminal, a resistance R3 between the (+) input terminal and an earth, a feedback resistance R4 and a capacitor C1 connected in parallel to an input resistance R1. The resistance R1 and the capacitor C1 compose a resonance circuit. The arrangement of the resonance capacitor C1 allows improvement in gain of a high frequency component of the differential amplification circuit 40.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a magnetic sensor used for coin selection and the like.

[0002]

BACKGROUND ART A conventional magnetic sensor used for coin selection uses a coil installed on the wall of a coin passage and the inductance of the coil changes when a coin approaches the coil. A sine wave current is passed through the coil, and its frequency is about several kHz. However, when trying to sort coins in this way, aluminum-based 1 yen, brass-based 5 yen, copper-based 10 yen, white copper-based 50 yen
It is possible to sort the coin series among yen series, 100 yen, and 500 yen, for example, white copper series 50 yen and 100 yen.
There is a drawback in that it is not possible to select between yen and 500 yen coins and 500 won copper-based coins.

To overcome this drawback, the Applicant has proposed a coin screening method which uses two signals of different frequencies. That is, the coil on the transmitting side and the coil on the receiving side are opposed to each other with the coin passage interposed therebetween, and a low-frequency current (for example, 10 kHz) and a high-frequency current (for example, 160 kHz) are alternately applied to the coil on the transmitting side to receive the coil on the receiving side. Both signals are received by the coil of and the lowest value of the low frequency voltage component,
The coins are sorted based on the lowest value of the high frequency voltage component. That is, if a coin exists between the coil on the transmitting side and the coil on the receiving side, an eddy current flows in the coin, which causes the electromagnetic field component generated on the transmitting side to be transmitted to the coil on the receiving side. Although the field component is attenuated, the amount of this attenuation varies from coin to coin, and even if two coins have the same amount of attenuation in a low frequency electromagnetic field, they have different amounts of attenuation in a high frequency electromagnetic field. Therefore, if two signals with different frequencies are used, the copper-based 500
It is possible to reliably select coins of almost the same shape such as a yen coin and a 500 won coin.

[0004]

By the way, when coins are selected based on the signal detected by the receiving coil as described above, the level of the signal detected by the receiving coil is very small. You need to increase the gain. Generally, an amplifier has a large gain at a low frequency but a small gain at a high frequency, and an amplifier having a large gain at a high frequency is expensive. As described above, when coins are selected using two signals having different frequencies, the cost of the amplifier is increased to increase the gain of the high frequency component, and the cost of the entire device is increased. There's a problem.

The present invention comprises a transmitter coil for passing a current having a predetermined frequency, and a receiver coil facing the transmitter coil and spaced apart from the transmitter coil by a predetermined distance. In the magnetic sensor that amplifies the signal received by the receiving coil with the amplifier and detects the DUT that passes through the gap based on the amplified signal, the gain of the high frequency component can be easily and inexpensively increased. It is intended to provide a magnetic sensor.

[0006]

According to the present invention, a resonance capacitor is connected in parallel with at least one of an input resistance of an amplifier for amplifying a signal received by a receiving coil and a receiving coil. is there.

[0007]

In the present invention, since the resonance capacitor is connected in parallel with at least one of the input resistance of the amplifier for amplifying the signal received by the receiving coil and the receiving coil, the signal received by the receiving coil is The gain of the high frequency component can be easily increased at low cost.

[0008]

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 is an explanatory view of an embodiment of the present invention.

In this figure, the signal generating circuit 10 is
It is a circuit that outputs a sine wave of 0 kHz and 160 kHz, and the switching of the frequency is controlled by the CPU 60. The transmission coil 20 is a coil that allows a current having a predetermined frequency to flow, and in the above embodiment, a sine wave current of 10 kHz and 160 kHz. The receiving coil 30 faces the transmitting coil 20, and the receiving coil 2
It is a coil that receives a signal from 0. Transmit coil 2
0 and the receiving coil 30 are wound on the ferrite cores 21 and 31, respectively, via bobbins (not shown). A coin passage 71 is provided between the transmission coil 20 and the reception coil 30, and the coin 70 rolls in the coin passage 71. In the coin passage 71, the transmission coil 20
The portion located between the receiving coil 30 and the receiving coil 30 is made of a material other than a conductor, for example, plastic. That is, the receiving coil 30 is an example of a receiving coil that faces the transmitting coil and that is provided at a predetermined distance from the transmitting coil.

The differential amplifier circuit 40 amplifies the signal received by the receiving coil 30, the diode 51 rectifies the output signal of the differential amplifier circuit 40, and the capacitor 52 rectifies the rectified signal. Is smoothed and the peak value of the data is held. The electric charge charged in the capacitor 52 is constantly discharged through the resistor 53, but the switch 53 discharges all the electric charge charged in the capacitor 52 at the time of frequency switching. , CPU60, 10kHz and 1
It is synchronized with the frequency switching of 60 kHz. The A / D conversion circuit 55 converts an analog signal indicating the voltage across the capacitor 52 into a digital signal.

In the above embodiment, the CPU 60 commands the signal generation circuit 10 to output a signal of 10 kHz, and the transmission circuit 20 supplies a current of the signal,
The receiving circuit 30 receives the signal of 10 kHz, and the amplifying circuit 4
0 is amplified, the diode 51 passes only its positive half-wave component, and the capacitor 52 holds the positive peak value. Although not shown in the figure, a diode connected to the output terminal of the amplifier circuit 40 and connected in the opposite direction to the diode 51, a capacitor for holding a negative peak value, and a resistor 53. , A switch similar to the switch 54, and a subtracter for obtaining the difference between the negative peak value and the positive peak value (that is, peak-peak value). Then, the peak-peak value is converted into a digital value by the A / D conversion circuit 55, and the CPU 60 takes in the digital value. next,
The CPU 60 commands the signal generation circuit 10 to output a signal of 160 kHz and the switch 54.
(And similar switch) is turned on to discharge the charge previously stored in the capacitor 52 (and similar capacitor) (ie reset the peak data of 10 kHz) and the transmitter circuit 20 sends a current of 160 kHz. The receiving circuit 30 receives the signal of 160 kHz, and then the amplification, the passage of the positive and negative half-wave components, the conversion of the peak-peak value of the 160 kHz component into a digital value, and the capturing thereof are performed.

Then, again, the above operation is performed for the signal component of 10 kHz, the above operation is performed for the signal component of 160 kHz, and a series of these operations is repeated. Then, the minimum value is selected from the peak values of the 160 kHz component. Based on these minimum values, it is determined what the inserted coin is and the selection is performed.

FIG. 2 is a circuit diagram showing a main part of the above embodiment.

The differential amplifier circuit 40 amplifies a signal generated at both ends of the receiving coil 30, and is a differential amplifier D.
Input resistance R1 to the-input terminal of A, input resistance R2 to the + input terminal, resistance R3 provided between the + input terminal and ground, feedback resistance R4, and input resistance R1 connected in series And a capacitor C1 that has been connected. In addition, the resistance R1,
The resistance values of R2, R3, and R4 are 1 kΩ and 1 k, respectively.
Ω, 12 kΩ, and 12 kΩ, and the capacitance of the capacitor C1 is 1000 pF.

In the above embodiment, the resonance circuit is constituted by the resistor R1 and the capacitor C1, and the resonance frequency f thereof is derived from the equation f = 1 / (2πRC) (1) In the case of the example, its resonant frequency is about 160 kHz. Note that R and C in the above formula
Is the resistance value and the capacitance value of the capacitor in the resonance circuit. Therefore, in the above embodiment, 160 kHz
At z, the gain of the differential amplifier circuit 40 is improved.

That is, when the capacitor C1 is not added in the differential amplifier circuit 40, the gain of the differential amplifier circuit 40 at 10 kHz is about 21.6 decibels,
The gain at 160 kHz is about 19.3 decibels, which is lower than that at 10 kHz. However, when the capacitor C1 is added as described above, the gain at 10 kHz does not change at 21 decibels, but the gain at 160 kHz is about 24. It becomes 9 decibels. That is, 16
The gain at 0 kHz is improved by the addition of the capacitor C1 by about 5.6 dB compared to before the addition. In the above decibel display, when the input level of the differential amplifier circuit 40 is V1 and the output level thereof is V2,
20 log ₁₀ (V2 / V1).

FIG. 3 is a circuit diagram showing another embodiment of the present invention, and is the same as the embodiment shown in FIG. 1 except for the differential amplifier circuit 41.

The differential amplifier circuit 41 is basically the same as the differential amplifier circuit 40, and is provided with a capacitor C2 instead of the capacitor C1. The capacitor C2 is
It is connected to both ends of the receiving coil 30 and its capacity is 1000.
pF.

In the embodiment shown in FIG. 3, the receiving coil 3
0 and the capacitor C2 form a resonance circuit, and the resonance frequency f thereof is derived from the equation f = 1 / (2π · (L · C) ^1/2 ). In this case, since the receiving coil 30 has an inductance of about 1 mH, its resonance frequency is about 160 kHz. Note that L and C in the above equation are the inductance value of the coil and the capacitance value of the capacitor in the resonance circuit. Therefore, in the above embodiment, the differential amplifier circuit 4 is operated at 160 kHz.
The gain of 0 is improved.

That is, when the capacitor C2 is not added in the differential amplifier circuit 41, the gain of the differential amplifier circuit 40 at 10 kHz is 21.6 decibels, and 1
The gain at 60 kHz is about 19.3 dB,
Although it is lower than the gain at 10 kHz, if the capacitor C2 is added as described above, the gain at 10 kHz does not change at about 21.6 decibels, but 160 kHz.
The gain at is about 29.6 dB. That is, 1
The gain at 60 kHz is improved by the addition of the capacitor C2 by about 10.3 dB compared to before the addition.

FIG. 4 is a circuit diagram showing still another embodiment of the present invention, which is the same as the embodiment shown in FIG. 1 except for the differential amplifier circuit 42.

The differential amplifier circuit 42 is basically the same as the differential amplifier circuit 40, and additionally has a capacitor C2 in addition to the capacitor C1. The capacitor C2 is
It is the same as the capacitor C2 in the embodiment shown in FIG.

In the embodiment shown in FIG. 4, the resistor R1 and the capacitor C1 form a resonance circuit, and the receiving coil 30 and the capacitor C2 form a resonance circuit. C
In the resonance circuit of 1 and 1, it is calculated by the formula (1), and
In the resonance circuit including the receiving coil 30 and the capacitor C2, it is calculated by the equation (2).

In the embodiment shown in FIG. 4, 160 kHz
The gain at z is about 40.0 decibels, 160k
The gain at Hz is improved by the addition of the capacitors C1 and C2 by about 20.7 decibels compared to before the addition.

It should be noted that the constants of the resistors, capacitors, and coils described above are merely examples, and constants other than the above constants may be adopted, and according to the frequency for which the gain is desired to be improved, equation (1),
The above constants are determined according to the equation (2).

In the above embodiment, the signal generation circuit 10
Is a circuit that outputs a sine wave signal of 10 kHz and a sine wave signal of 160 kHz. However, a signal of a frequency other than the above frequency may be output, and three or more signals of different frequencies are output. You may do it. Further, the ferrite cores 21 and 31 may be omitted.

Further, although the above embodiment is an example of a coin sensor for selecting coins, it can be used as a magnetic sensor for detecting an object to be measured other than coins.

[0028]

According to the present invention, a transmitting side coil for supplying a current having a predetermined frequency, and a receiving side coil facing the transmitting side coil and spaced apart from the transmitting side coil by a predetermined distance. And amplifying the signal received by the receiving coil with an amplifier, and based on this amplified signal,
In the magnetic sensor for detecting the object to be measured passing through the gap, it is possible to easily and inexpensively increase the gain of the high frequency component.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of the present invention.

FIG. 2 is a circuit diagram showing a main part of the embodiment.

FIG. 3 is a circuit diagram showing another embodiment of the present invention.

FIG. 4 is a circuit diagram showing another embodiment of the present invention.

[Explanation of symbols]

 20 ... Transmission coil, 30 ... Reception coil, 40 ... Differential amplifier circuit, C1, C2 ... Capacitor, DA ... Differential amplifier.

Claims (2)

[Claims] 1. A receiver coil comprising: a transmitter coil for supplying a current having a predetermined frequency; and a receiver coil facing the transmitter coil and spaced apart from the transmitter coil by a predetermined distance. A magnetic sensor for amplifying a signal received by a side coil with an amplifier and detecting an object to be measured passing through the gap based on the amplified signal, wherein at least one of the input resistance of the amplifier and the receiving side coil is included. A magnetic sensor characterized in that a resonance capacitor is connected in parallel with one of them. 2. The transmission coil according to claim 1, wherein currents having two or more frequencies different from each other flow in the coil, and the resonance frequency of the resonance capacitor is any one of the two or more frequencies. A magnetic sensor having a frequency substantially the same as the frequency.