JP2002071644A - Water content measuring method and device having metal piece detecting function, and garbage disposal device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a low-cost garbage disposal device B capable of measuring the water content of an examined object and discriminating whether a metal piece is mixed in the examined object in a short time. SOLUTION: This garbage disposal device B with a water content measuring system A built inside, a metal piece detecting and water content computing part 73 extracts the water content from a correlation expression 811 by applying circuit currents Ia, Ib detected by a current detecting part 72 in the connected state of capacitors 51, 52, to inductance L-circuit current I characteristics 91, 92. In the case the extracted water content is in a range of 0%-100%, an actuator controller 3 controls an actuator 2 on the basis of the extracted water content. In the case the extracted content is outside the range, an alarm 31 is driven, determining the intrusion of a metal piece in the examined object.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a moisture content measuring method and a moisture content measuring device having a metal piece detecting function, and a garbage disposal device.

[0002]

2. Description of the Related Art Japanese Unexamined Patent Publication No. Hei 8-178879 discloses a garbage disposer equipped with a moisture content sensor having a heating means and a temperature sensor (prior art 1). In addition, infrared light containing a plurality of wavelengths is applied to snow to detect the intensity of reflected light, and the ratio of the intensity of reflected light is compared with correlation data that has been calculated in advance to derive the water content of snow. An inspection device (prior art 2) is also known.

[0003]

The above prior art has the following problems. In the prior art 1, since it is necessary to raise the temperature, it takes a considerable time from the start to the end of the inspection and also requires a large amount of energy. Further, only the moisture content of a part of the object can be detected. Conventional technology 2
However, the manufacturing cost of the moisture inspection device is enormous. Further, only the moisture content of a part of the object can be detected.

Further, in the garbage processing apparatus, if metal pieces are mixed in the garbage to be processed, there is a possibility that the stirring portion and the processing tank may be damaged. On the other hand, as a technique for detecting a metal, for example, there is a technique disclosed in Japanese Patent Publication No. 2009270. In this technology, a sensor coil is provided at the tip made of a non-magnetic material, a pulse-like current waveform is applied to the coil, the supply of the current waveform is stopped, and the presence or absence of metal is determined based on the transient response time at that time. are doing. However, since the transient response time is extremely short, it is not possible to accurately determine the presence or absence of metal, and it takes time. In order to improve the accuracy, the application and the stop of the application are repeated a plurality of times, so that it takes a considerable time for the determination.

SUMMARY OF THE INVENTION It is an object of the present invention to measure in a short time the moisture content of a test object and to determine whether or not a metal piece is mixed in the test object. An object of the present invention is to provide a moisture content measuring method having a function, a moisture content measuring device having a metal piece detecting function, and a garbage disposal device.

[0006]

[Means for Solving the Problems] [Claims 1 and 3] In the following manner, it is determined whether or not a metal piece is mixed in a test object, and the water content of the test object is measured. I do. Although the volume of each sample is the same, a container containing each sample set at a known different moisture content is placed in the hollow of the coil, and a physical quantity correlated with the moisture content of the sample is extracted, and the moisture content of each sample is extracted. The correlation between the water content and the extracted physical quantity is recorded, and a container containing the specimen whose volume is the same as that of the sample for which the correlation was measured, but whose water content is unknown is placed in the hollow of the coil. do it,
A physical quantity correlated with the moisture content of the test object is extracted, and if the extracted physical quantity is within the range of the correlation, the extracted physical quantity is compared with the recorded correlation to determine the water content of the test object. The ratio is determined, and when the extracted physical quantity is out of the range of the correlation, it is determined that a metal piece is mixed in the test object. The physical quantities are the inductance of the coil, the relative permeability and the magnetic susceptibility of the sample and the test object. {In the case where the physical quantity is an inductance} In a finite-length coil, the inductance L is represented by the following Equation 1.

(Equation 1) When a substance (sample or test object) is put into the hollow portion of the coil, the relative magnetic permeability changes according to the type and volume of the substance. For example, the relative permeability of air is (1 + 3.65 × 10 ⁻⁷ ), and the relative permeability of water is (1−0.88 × 10 ⁻⁵ ). Moisture content x
% Of the sample is placed in the hollow of the coil with the sample placed in the container, and the inductance L (x) is measured.

(Equation 2)

When this equation 2 is transformed into an equation of x, the following equation 3 is obtained.

(Equation 3) A container having the same volume as that of the sample, but containing a specimen whose moisture content is unknown is arranged in the hollow of the coil, and the inductance L of the coil is measured. Measured inductance L
By substituting the value of (x) into Equation 3, the moisture content x% of the test object can be calculated. When a metal piece is mixed in the test object, the inductance L changes sharply,
It turns out that a metal piece is mixed in the test object. For example,
When aluminum metal pieces are mixed, x>
It becomes an abnormal value of 100. When a diamagnetic material is mixed, x <0, which is an abnormal value.

{When the physical quantity is relative magnetic permeability} In Equation 1, the relative magnetic permeability at the moisture content x is set to μ _S (x), and Equation 2 = Equation 1 is obtained. Can be

(Equation 4)

A container having the same volume as that of the sample but containing an object whose water content is unknown is placed in the hollow of the coil, and the inductance L of the coil is measured. determine the magnetic permeability μ _S. The by substituting the value of relative magnetic permeability mu _S to the number 3 water content x% of the test object can be calculated.

When a metal piece is mixed in the test object, it can be seen that the metal piece is mixed in the test object because the inductance L changes sharply. For example, when aluminum metal pieces are mixed,
x> 100, which is an abnormal value. When a diamagnetic material is mixed, x <0, which is an abnormal value.

{When the physical quantity is magnetic susceptibility} The magnetic susceptibility is expressed by the following equation (5).

(Equation 5) The susceptibility and relative magnetic permeability at the moisture content x are represented by X, respectively.
(X), μ _S (x), and substituting equation 5 into equation 4 and rearranging, equation 6 is obtained.

(Equation 6) A container having the same volume as that of the sample, but containing a specimen whose moisture content is unknown is placed in the hollow of the coil, the inductance L of the coil is measured, and the magnetic susceptibility X of the specimen is calculated from Equation 6. Ask. By substituting the value of the magnetic susceptibility X into Equation 6, the moisture content x% of the test object can be calculated.

When a metal piece is mixed in the test object, it can be seen that the metal piece is mixed in the test object because the inductance L changes sharply. For example, when aluminum metal pieces are mixed,
x> 100, which is an abnormal value. When a diamagnetic material is mixed, x <0, which is an abnormal value.

The container must be made of a material (eg, resin) that is hardly magnetized by water. By using the above water content measurement method, a large amount of energy is not required for the measurement, and the water content of the entire test object can be measured at a low cost in a short time.

[Claims 2 and 3] As described below, it is determined whether or not a metal piece is mixed in a test object.
The moisture content of the test object is measured. The volume of each sample is the same, but a container containing each sample set at a known different moisture content is arranged in the hollow of the coil, the coil is connected to a high-frequency power source, and a voltage waveform and A phase difference of the current with respect to the voltage is obtained from the current waveform, and a physical quantity correlated with the water content of the sample is calculated and obtained from the current value, the voltage value, and the phase difference. The correlation between the water content and the physical quantity of each sample is recorded. A test object having the same volume as each of these samples, but having an unknown moisture content, is placed in a container, placed in the hollow of a coil, and the coil is connected to a high-frequency power source, and a voltage waveform and a current waveform are measured. The phase difference of the current with respect to the voltage is measured, and a physical quantity correlated with the water content of the test object is calculated from the current value, the voltage value, and the phase difference. If the physical quantity is within the range of the correlation, the physical quantity and the recorded correlation are collated to determine the moisture content of the test object. When the physical quantity is out of the range of the correlation, it is assumed that a metal piece is mixed in the test object. The physical quantities are the inductance of the coil, the relative permeability and the magnetic susceptibility of the sample and the test object.

For example, when the physical quantity is the inductance of the coil, it is calculated and calculated based on the following equation (7).

(Equation 7)

When a metal piece is mixed in the test object, it can be seen that the metal piece is mixed in the test object because the inductance L changes sharply. For example, when aluminum metal pieces are mixed,
x> 100, which is an abnormal value. When a diamagnetic material is mixed, x <0, which is an abnormal value.

The container must be made of a material (eg, resin) that is hardly magnetized by water. By using the above water content measurement method, a large amount of energy is not required for the measurement, and the water content of the entire test object can be measured at a low cost in a short time.

[Claim 4] In the following manner, it is determined whether or not a metal piece is mixed in the test object and the moisture content of the test object is measured. Moisture content is 0% to 1 in a given volume
The correlation between the water content and the inductance of the coil when the container containing the sample and the test object of 00% is placed in the hollow of the coil is recorded. Connecting a coil, a first capacitor, and a resistive load to form a first tuning circuit;
When a container containing a sample of a predetermined volume having a water content of 0% is placed in the hollow of the coil, the inductance of the coil, the capacity of the first capacitor, And the frequency of the high frequency power supply. When a container containing a sample of a predetermined volume having a water content of 100% is placed in the hollow of the coil, the second tuning circuit in which the first capacitor is changed to the second capacitor is brought into a resonance state so as to be in a resonance state. The capacity of the capacitor 2 is set. A specimen having the same volume as the sample, but having an unknown moisture content, is placed in a container and placed in the hollow of the coil, and the first tuning circuit is connected to a high-frequency power supply to connect the first circuit current and the first circuit current. 1 is measured. The same test object is placed in the container and placed in the hollow of the coil, and the second tuning circuit is connected to a high-frequency power source to measure the second circuit current and the second load voltage. From the first circuit current or the first load voltage and the second circuit current or the second load voltage, when the specimen whose moisture content is unknown is placed in the container and placed in the hollow of the coil. Calculate the inductance of the coil. If the calculated inductance is within the range of the correlation, the moisture content of the test object is obtained from the correlation. If the calculated inductance is out of the range of the correlation, it is assumed that a metal piece is mixed in the test object.

For example, in the case of an RLC resonance circuit in which a coil of a resistor R, a capacitor C, and an inductance L are connected in series, when a high frequency of a frequency f (Hz) and a voltage V (V) is applied, a circuit current I flowing through the circuit becomes It is expressed by the following equation (8).

(Equation 8)

From equation (8), it is clear that the circuit current I is a function of the inductance L, and the capacitor C _rc is set so as to be in a resonance state when the inductance L _rc . That is, the second term in the square root of the denominator of Equation 8 is set to be zero. When the capacitor C satisfies the following equation 9, the circuit current I becomes maximum.

(Equation 9)

By substituting Equation 2 into Equation 8, Equation 10 of the correlation between the circuit current I and the water content x is obtained.

(Equation 10)

Further, when the water content x is expressed as a function of the circuit current I with respect to Equation 10, the following Equation 11 is obtained.

[Equation 11]

In the above equation (11), the solution cannot be determined even if the circuit current I is specified. Therefore, the capacitor C _{rc (x = 0)} which is in a resonance state when the water content x is 0% is selected, and the water content x
Is in a resonance state when is 100%.
_{rc (x = 100)} is selected, and the current I _{x = 0 of the} circuit which is in a resonance state when the water content x is 0%, and the current I _{x = 100 of the} circuit which is in a resonance state when the water content x is 100%. Accordingly, it is possible to determine whether or not a metal piece is mixed in the test object and calculate the water content x.

The container must be made of a material (eg, resin) that is hardly magnetized by water. By using the above water content measurement method, a large amount of energy is not required for the measurement, and the water content of the entire test object can be measured at a low cost in a short time.

[0025] [Claims 5 and 6] A moisture content measuring device having a metal piece detecting function comprises: a coil having a hollow portion;
A container for placing a sample or a test object and disposed in a hollow portion, and a first physical amount extracting means for extracting a physical amount correlated to the water content of the sample when the container containing the sample is disposed in the hollow portion of the coil. ,
Correlation recording means for recording the correlation between each physical quantity extracted from each sample set to a known different moisture content and moisture content at the same volume, and the moisture content is unknown and the volume is the same as each sample. A second physical quantity extracting means for extracting a physical quantity correlated with the moisture content of the test object when the container containing the test object is arranged in the hollow of the coil; and the measured physical quantity is out of the range of the correlation. In some cases, the metal piece detecting means that the metal piece is mixed in the test object, and when the metal piece detecting means determines that the metal piece is not mixed in the test object, A water content calculating means for calculating the water content of the test object by comparing the correlation with the correlation recorded in the correlation recording means. The physical quantities are the inductance of the coil, the relative permeability and the magnetic susceptibility of the sample and the test object.

The water content measuring device having a metal piece detecting function determines whether or not a metal piece is mixed in the test object and measures the water content of the test object as follows. . First,
The second physical quantity extracting means extracts a physical quantity correlated with the water content of the sample or the test object when the container containing the sample or the test object is arranged in the hollow of the coil. The correlation recording unit records the correlation between each physical quantity extracted from each sample set to a different known moisture content with the same volume and the moisture content. If the measured physical quantity is out of the range of the correlation, the metal piece detecting means determines that the metal piece is mixed in the test object.
The water content calculating means, when the metal piece detecting means determines that the metal piece is not mixed in the test object, compares the physical quantity with the correlation recorded in the correlation recording means, and Is calculated.

The container must be made of a material (eg, resin) that is hardly magnetized by water. By using the water content measuring device having the above-mentioned metal piece detection function, a large amount of energy is not required, and in a short time, the water content of the test object can be measured and whether the metal piece is mixed in the test object. The determination of whether or not it is possible can be performed at low cost.

[Regarding Claim 7] The garbage disposal apparatus comprises:
A decomposition tank for decomposing garbage by aerobic microorganisms,
7. A moisture content measurement having an actuator for maintaining the inside of the decomposition tank in an environment suitable for the activity of microorganisms, and a controller for controlling the actuator, and having a metal piece detection function according to claim 5 or 6. In addition to attaching the device, if the metal piece detecting means determines that the metal piece is mixed in the test object, the metal piece notifying means for informing the user to remove the mixed metal piece is hydrated. When the metal piece detecting means determines that the metal piece is mixed in the test object, the controller prohibits the control of the actuator and when the metal piece is mixed in the test object. When the metal piece detecting means determines that there is no garbage, the actuator is controlled based on the detected moisture content of the garbage.

That is, in the garbage disposal apparatus, when a metal piece is mixed in the test object, the metal piece notifying means performs a notification for urging the user to remove the mixed metal piece, and the controller operates the controller. Since the control of the actuator is prohibited, breakage can be prevented.
Further, when no metal pieces are mixed, the actuator is controlled so as to be suitable for the water content, so that the garbage can be efficiently decomposed.

[0030]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention (Claims 1 to 7)
Will be described with reference to FIGS. As shown in FIG. 1, a water content measurement system A having a metal piece detection function
Has a decomposition tank 1 for decomposing garbage by aerobic microorganisms, an actuator 2 for maintaining the inside of the decomposition tank 1 in an environment suitable for the activity of microorganisms, and an actuator controller 3 for controlling the actuator 2. It is assembled in the garbage disposal device B.

The coil 4 has an inner diameter of 66.5 mm, a coil winding diameter of 70.5 mm, a height of 102 mm, and a wire diameter of 0.5 m.
m is a copper wire wound around a bobbin 40 192 times with no gap.

When the coil 4 has an inductance value when a test object or a sample having a water content of 0% is disposed in the hollow portion 41, the coil 4
The constant is set so that the RLC circuit 7 in which the resistor 6 and the resistor 6 are connected in series is in a resonance state and the circuit current I is maximized.

The condenser 52 has a water content of 100%.
% When the test object or the sample is disposed in the hollow portion 41 and the coil 4 has an inductance value, the RLC circuit 7 in which the coil 4, the capacitor 52, and the resistor 6 are connected in series becomes a resonance state. The constant is set so that the circuit current I becomes maximum.

5 is a capacitor 5 constituting the RLC circuit 7
This is a changeover switch for switching between 1 and 52, and is operated by a control signal of a microcomputer (not shown) of the measurement controller 70.

Reference numeral 71 denotes a high-frequency power supply, and reference numeral 72 denotes a current detector for detecting a circuit current I flowing in the RLC circuit 7. Reference numeral 73 denotes a metal piece detection and moisture content calculation unit.

Next, the operation of the water content measurement system A (measurement / storage of water content-inductance characteristics, presence / absence of mixing of metal pieces, calculation of water content, actuator control) will be described with reference to the flowcharts shown in FIGS. State. [Measurement and storage of water content-inductance characteristics] As shown in FIG. 2, an impedance meter 81 is connected to the coil 4, and nine types of samples whose water content is known (0% to 100%) are made of plastic one by one. And placed in the hollow portion 41 of the coil 4, and the inductance of the coil 4 is measured by an impedance meter 81 for each sample.

The water content-inductance characteristic measuring / storing unit 74 calculates the moisture content-inductance characteristic based on the above-described inductance measuring result.
A correlation equation 811 indicating a correlation between the water content and each measured inductance is calculated and stored in a memory (not shown).

[Measurement of Circuit Current I When Capacitors 51 and 52 are Connected] Next, as shown in FIG. 1, an RLC circuit 7 in which a coil 4, a capacitor 51 (or a capacitor 52), and a resistor 6 are connected in series is provided. A garbage (test object) having the same volume as each sample but an unknown water content is connected to a high frequency power supply 71 and placed in a plastic container 42 and placed in the hollow portion 41 of the coil 4. , The operation of detecting the circuit current I by the current detection unit 72 is performed.

The memory (not shown) of the characteristic storage unit 9
Stores the following characteristics. Reference numeral 91 denotes an inductance L-circuit current I characteristic in which the capacitor 51 is connected to the RLC circuit 7 and the RLC circuit 7 enters a resonance state when a test object having a water content of 0% is put into the hollow portion 41. Reference numeral 92 denotes an inductance L-circuit current I characteristic in which the capacitor 52 is connected to the RLC circuit 7 and the RLC circuit 7 enters a resonance state when a test object having a water content of 100% is put into the hollow portion 41.

At step s 1, the measurement controller 7 switches the movable contact of the changeover switch 5 to the capacitor 51 side.
The microcomputer 0 (not shown) sends out a control signal. In step s2, the current detection unit 72 detects the circuit current I
a is detected and stored in a memory (not shown).

In step s3, the metal piece detection and moisture content calculation unit 73 applies the circuit current Ia detected in step s2 to the inductance L-circuit current I characteristic 91 to extract solution candidates 911 and 912, and stores them in the memory ( (Not shown).

In step s4, the measurement controller 7 is switched so that the movable contact of the changeover switch 5 is switched to the capacitor 52 side.
The microcomputer 0 (not shown) sends out a control signal. In step s5, the current detection unit 72 determines that the circuit current I
b is detected and stored in a memory (not shown).

In step s6, the metal piece detection and moisture content calculation unit 73 applies the circuit current Ib detected in step s5 to the inductance L- circuit current I characteristic 92 to extract solution candidates 921 and 922, (Not shown).

In step s7, solution candidate 911 = solution candidate 9
21 is determined by the metal piece detection / moisture content calculating unit 73, and when the solution candidate 911 = the solution candidate 921 (YE
In S), the process proceeds to step s12. When the solution candidate 911 ≠ the solution candidate 921 (NO), the process proceeds to step s8.

In step s8, solution candidate 911 = solution candidate 9
22 is determined by the metal piece detection and moisture content calculation unit 73, and when the solution candidate 911 = the solution candidate 922 (YE
In S), the process proceeds to step s12. When the solution candidate 911９the solution candidate 922 (NO), the process proceeds to step s9.

In step s9, solution candidate 912 = solution candidate 9
21 is determined by the metal piece detection / moisture content calculation unit 73, and when the solution candidate 912 is the solution candidate 921 (YE
In S), the process proceeds to step s11. If the solution candidate 912 ≠ the solution candidate 921 (NO), the process proceeds to step s10.

In step s10, the metal piece detecting and moisture content calculating unit 73 determines whether or not the solution candidate 912 = the solution candidate 922. If the solution candidate 912 = the solution candidate 922 (YE)
In S), the process proceeds to step s11.

In step s11, the solution candidate 9 is added to the correlation equation 811.
12 and the process proceeds to step s12. Step s12
Substitute the solution candidate 911 into the correlation equation 811 in step s1
Proceed to 3.

In step s13, the metal piece detecting and moisture content calculating section 73 extracts the moisture content from the correlation equation 811.
Proceed to 14. In step s14, the metal piece detection and moisture content calculation unit 73 determines whether or not the extracted moisture content is in the range of 0% to 100%, and if it is in the range of 0% to 100% (YES). ), The process proceeds to step s15, and if it is out of the range (NO), it is determined that a metal piece is mixed in the test object, and the process proceeds to step s16.

At step s15, the actuator controller 3 performs the following actuator control. Steps
At 16, the actuator controller 3 maintains the actuator 2 in the stopped state, and proceeds to step s17. Steps
At 17, the actuator controller 3 activates the alarm 31.

[Actuator Control] The garbage whose moisture content has been measured is discharged from the container 42 and discharged into the decomposition tank 1. Actuator controller 3 based on the extracted moisture content
Controls the actuator 2. Actuator 2 is
A motor of a stirrer for stirring garbage deposited in the decomposition tank 1, a motor of a ventilation fan for ventilation, an electric heater for controlling the temperature in the decomposition tank 1, and the like.

This embodiment has the following advantages. [A] Moisture content measurement system A equipped with metal piece detection function
Does not require a large amount of energy and measures the water content of garbage (test object) with unknown water content in a short time and determines whether metal chips are mixed in the garbage. be able to. When metal pieces are mixed in the garbage, the actuator controller 3 keeps the actuator 2 in a stopped state, and the alarm 31 is activated to prompt the user to remove the metal pieces. There is no fear that the tank 1 is damaged. In addition, when no metal pieces are mixed, the actuator 2 is controlled so as to be suitable for the water content, so that garbage can be efficiently decomposed.

[A] The water content measurement system A having a metal piece detection function can be manufactured at low cost, and consumes little energy for measuring the presence or absence of metal pieces and the water content.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram of a garbage disposal apparatus according to one embodiment of the present invention, in which a moisture content measuring system having a metal piece detecting function is assembled.

FIG. 2 is an explanatory diagram showing a manner of calculating a correlation equation showing a correlation between a water content and an inductance by using the water content measurement system having the metal piece detecting function.

FIG. 3 is a flowchart showing an operation of the moisture content measuring system having the metal piece detecting function.

FIG. 4 is a flowchart showing the operation of the moisture content measurement system having the metal piece detection function.

[Explanation of symbols]

A water content measurement system (water content measurement device) B garbage disposal device I circuit current (physical quantity) Ia circuit current (first circuit current) Ib circuit current (second circuit current) 1 decomposition tank 2 actuator 3 actuator control Container (controller) 4 Coil 31 Alarm (metal piece notification means) 41 Hollow part 42 Container 51 Capacitor (first capacitor) 52 Capacitor (second capacitor) 71 High-frequency power supply 72 Current detector (second physical quantity extraction means) 73 Metal piece detection and moisture content calculation unit (metal piece detection means,
Moisture content calculating means) 74 Moisture content-inductance characteristic measurement / storage unit (correlation recording means) 81 Impedance meter (first physical quantity extracting means)

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Takahiro Mita 1-1-1, Showa-cho, Kariya-shi, Aichi Pref. F term (reference) 2G053 AA13 AA21 AB06 AB07 BA02 BC14 CA03 CA17 CA18 4D004 AA03 AB03 CA15 CA19 CA22 CA50 CB01 CB32 CB50 DA01 DA02 DA04 DA06 DA09 DA13 DA16 DA20

Claims (7)

[Claims] 1. A container containing each sample having the same volume but set to a known different moisture content is placed in the hollow of the coil to extract a physical quantity correlated with the moisture content of the sample. Then, the correlation between the moisture content of each sample and the extracted physical quantity is recorded, and the volume of each sample measured for this correlation is the same,
The container containing the specimen whose moisture content is unknown is arranged in the hollow of the coil, and a physical quantity correlated with the moisture content of the specimen is extracted, and the extracted physical quantity is within the range of the correlation. If the extracted physical quantity is outside the range of the correlation, the extracted physical quantity is compared with the recorded correlation to determine the moisture content of the test specimen. Moisture content measurement method provided with a metal piece detection function that assumes that metal pieces are mixed in the water. 2. A container containing each sample having the same volume but set to a known different moisture content is disposed in the hollow of the coil, and the coil is connected to a high-frequency power source, so that each sample has a different water content. The phase difference of the current with respect to the voltage is obtained from the voltage waveform and the current waveform, and a current value, a voltage value, and a physical quantity correlating with the water content of the sample are calculated from the phase difference. The correlation with the physical quantity is recorded, and a test object having the same volume as each of these samples but having an unknown water content is placed in a container and placed in the hollow of the coil, and the coil is set to a high frequency. Connect to a power supply, measure the voltage waveform and the current waveform, determine the phase difference of the current with respect to the voltage, and calculate the physical quantity correlated with the water content of the test object from the current value, the voltage value, and the phase difference And if this physical quantity is within the range of the correlation, To determine the moisture content of the test object by collating the physical quantity and the recorded correlation, if the physical quantity is out of the range of the correlation, a metal piece is mixed into the test object. A moisture content measurement method provided with a metal piece detection function. 3. The water content measurement provided with a metal piece detecting function according to claim 1, wherein the physical quantity is an inductance of the coil, a relative magnetic permeability or a magnetic susceptibility of the sample or the test object. Method. 4. A correlation between the water content and the inductance of the coil when a container having a predetermined volume and a sample having a water content of 0% to 100% and an object is placed in the hollow of the coil. When the coil, the first capacitor, and the resistive load are connected to form a first tuning circuit, and a container containing a predetermined volume of a sample having a water content of 0% is disposed in the hollow of the coil. Then, the inductance of the coil, the capacity of the first capacitor, and the frequency of the high-frequency power supply are set so that the first tuning circuit is in a resonance state, and the water content is a predetermined volume of 100%. When a container containing a sample is placed in the hollow of the coil, the capacity of the second capacitor is changed so that the second tuning circuit in which the first capacitor is changed to the second capacitor is in a resonance state. Set ; Then, although the volume is the same as the sample, placed in the hollow of the coil putting the moisture content test object unknown to the container, the first
The first tuning circuit is connected to the high-frequency power source to measure a first circuit current and a first load voltage, and the same test object is placed in a container and placed in the hollow of the coil, and the second tuning is performed. A circuit is connected to the high-frequency power supply to measure a second circuit current or a second load voltage, and the first circuit current or the first load voltage and the second circuit current or the second From the load voltage, calculate the inductance of the coil when the test object whose moisture content is unknown is placed in a container and placed in the hollow of the coil, and the calculated inductance is within the range of the correlation. In some cases, the moisture content of the test object is determined from the correlation, and when the calculated inductance is out of the range of the correlation, the detection of a metal piece that a metal piece is mixed in the test object is performed. Moisture content measurement method with functions. 5. A coil having a hollow portion, a container for placing a sample or a test object and disposed in the hollow portion, and the sample when the container containing the sample is disposed in the hollow portion of the coil. Extraction of physical quantities correlated to the water content of
Physical quantity extraction means, correlation recording means for recording the correlation between each physical quantity and moisture content extracted from each sample set to a known and different moisture content in the same volume, the moisture content is unknown, each said A second physical quantity extracting means for extracting a physical quantity correlated to the water content of the test object when a container containing the test object having the same volume as the sample is arranged in the hollow of the coil; When the physical quantity is out of the range of the correlation, the metal piece detecting means that the metal piece is mixed in the test object, and the metal piece detection when the metal piece is not mixed in the test object When the means has determined, the metal piece detection function having a water content calculating means for calculating the water content of the test object by comparing the physical quantity and the correlation recorded in the correlation recording means. Equipped with a moisture content measuring device. 6. The moisture content measuring apparatus according to claim 5, wherein the physical quantity is an inductance of the coil, a relative magnetic permeability or a magnetic susceptibility of the sample or the test object. 7. A decomposition tank for decomposing garbage with aerobic microorganisms, an actuator for maintaining the decomposition tank in an environment suitable for the activity of the microorganisms, and a controller for controlling the actuator. In the refuse treatment device, a moisture content measuring device having the metal piece detecting function according to claim 5 or 6 is additionally provided, and when a metal piece is mixed in the test object, the metal piece detecting means is provided. If it is determined, a metal piece notifying unit for notifying the user of removal of the mixed metal piece is attached to the moisture content measuring device, and the controller has the metal piece mixed in the test object. And the metal piece detecting means determines that the control of the actuator is prohibited, and if the metal piece detecting means determines that no metal piece is mixed in the test object, the garbage is detected. The test object is Garbage disposal unit and controls said actuator based on moisture content.