JPH09215670A - Digital type radiation inspecting instrument - Google Patents

Abstract

PROBLEM TO BE SOLVED: To achieve a quick and accurate measurement of the intensity and waveform of radiation with a microscopic length at a high accuracy as radiated from a human body owing to the imbalance of a nerve system based on cranial nerves. SOLUTION: This inspecting instrument comprises an inspecting instrument unit A, a sensor combined with the inspecting instrument unit to measure the intensity and waveform of a radiation R and an information control section 10 to digitally process a signal detected by the sensor. This achieves a measurement at a high accuracy of the intensity and the waveform of the radiation R with a millimeter wavelength and a micro wavelength generated from a human body.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is highly accurate in measuring radiation of a very long wavelength emitted from a human body due to imbalance of a nervous system based on, for example, a cranial nerve. The present invention relates to a digital radiological inspector for quick and reliable measurement.

[0002]

2. Description of the Related Art It is widely known that humans carry out normal life activities by virtue of a control system called the cranial nervous system. When humans are exposed to physical stress, mental stress, and even biochemical stress (distress, pain, pressure, weighting, anxiety, shock, etc.), these are the first major stresses in the brain and nervous system. An unbalance occurs in the action potential of the muscle. If this confusion accumulates every day, the cranial nerves and muscles will be damaged, causing abnormal changes in the normal functions of various parts of the human body. This is manifested as low back pain, headache, numbness, stiff shoulder, decreased internal organ function and abnormalities, and further autonomic imbalance, asthma, high (low) blood pressure, psychogenicity, rheumatoid arthritis, It induces many diseases such as Graves' disease, intractable diseases and cancer. It is known that when there is functional damage to the cranial nerve tissue, the human body emits radiation with a wavelength of millimeter length (hereinafter referred to as millimeter wavelength) through the brain and whole nerve tissue. Also, the brain itself has no damage or accumulation of stress and does not emit radiation, but there are pathogenic sites or functional disorders in other parts of the body, or forced stress is applied to balance the action potential of muscles. Even when disturbed, a small amount of radiation is emitted from the site. Therefore, by measuring the level of millimeter-wave radiation in a normal state, measuring how much the radiation differs when sick or abnormal, and comparing it, the degree of the symptom can be known. Conventionally, as a radiation inspector for detecting such radiation, it is composed of a lens provided at one end in the inspector with a space and an adjustable inspection plate provided at the other end in the inspector. There was something. This is a sensory and subjective method in which radiation emitted from the human body is focused by the lens and an inspector inspects the inspection plate with his fingertip.

[0003]

The above-mentioned conventional radiation inspection device detects the radiation emitted from the human body, but does not have the function of measuring the intensity of the radiation. For this reason, among the central and peripheral nerve systems that connect to the cranial nerves, the CNC (Criti) of nerve bundles with a diameter of about 1 mm or less scattered about 50 to 60 in the whole body as the main nerve center.
Cal Nerve Center) is used to find the central part of nerve stress as a pathological site with dysfunction, and when this CNC is subjected to an operation such as pressing at a predetermined site in a predetermined order, the brain becomes beta. In the burst state, the stress accumulated mainly in the hypothalamus of the brain could not be removed. The frequency is about 6
Since it is limited to the detection of radiation of millimeter wavelength near 9.5 Hz, it is possible to detect any intensity signal when the frequency of radiation emitted from the human body is higher or lower. Can not. In addition, it is difficult to obtain the one suitable for the actual situation because it does not have the function of measuring several kinds of radiation in various bands of minute length.

The present invention solves the inconveniences of the above-mentioned conventional radiation inspectors, and measures the intensity and waveform of the radiation emitted from the human body with high precision while detecting it with high precision. Then, the position of the nerve stress center is properly found, and the measured values of radiation can be easily processed, recorded, and read out, and the nerve stress center is continuously observed until the functional disorder disappears. The purpose is to normalize the neuropathy and normalize the functions of various parts of the human body.

[0005]

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and the present invention according to claim 1 is combined with an inspector unit and the inspector unit to obtain the intensity and waveform of radiation. A means is used which is composed of a sensor for measuring the temperature and an information control unit for digitally processing the signal detected by the sensor.

According to a second aspect of the present invention, there is provided a substantially cylindrical body according to the first aspect, a cover rotatably screwed to a body wall at one end of the body and provided with a sensor on one side, and the cover. It has a bottomed cylindrical shape with an open side, and has a horn that expands outward from a throttle hole provided in the center of the partition wall, and was mounted inside the body so that the horn opens at the other end of the body. A means for measuring the intensity and waveform of the radiation by the length of the chamber formed by the focusing chamber and between the aperture and the sensor was adopted.

The present invention according to claim 3 provides the invention according to claim 1.
Alternatively, in the second aspect, a means is adopted in which a plurality of the inspector units are used and radiation is detected at a plurality of locations at the same time, and the intensity and waveform of the radiation are measured.

The present invention according to claim 4 provides the invention according to claim 1.
Alternatively, in claim 2, the sensor is provided so as to be connectable to the information control unit via an A / D converter.

According to a fifth aspect of the present invention, in any one of the first, second, and fourth aspects, the sensor is positive or negative in a hermetically sealed container in which an inert gas such as argon is sealed. This means is an ionization chamber which is provided with the electrodes facing each other and is provided with a detection unit which allows radiation particles to pass between the electrodes in the crossing direction.

According to a sixth aspect of the present invention, in the sensor according to any one of the first, second and fourth aspects, the sensor has a crystalline property of silicon or germanium having an insulating coating film deposited on one side. The positive and negative electrodes are provided on both sides of the semiconductor plate material so as to face each other, and a means of being a semiconductor type of a diode structure that exhibits electrical conductivity in one direction is adopted.

Further, the invention according to claim 7 employs a means in which the signal line routed between the sensor and the information control section in claim 1 or claim 4 is an optical fiber.

Further, the present invention according to claim 8 provides the invention according to claim 1.
Alternatively, the measured value or the waveform of the intensity of the radiation detected by the sensor is converted from an analog signal to a digital signal by an A / D converter, and the digital signal can be recorded in the information control unit. A means of being stored and readable is adopted.

According to a ninth aspect of the present invention, in the information control section according to the first or fourth aspect, an external input device such as a keyboard is connected to the information control section, and the measured value of the intensity of the radiation, the waveform, etc. are individually provided. In addition, a means for connecting an external output device such as a display or a printer for displaying at a desired plurality of places is adopted.

[0014]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be specifically described below with reference to the drawings. 1 to 10 show an embodiment of the present invention. This digital radiological inspection apparatus includes a body 1, a cover 2, a focusing chamber 3 and a radiation R.
In addition to using a plurality of inspector units A formed by a sensor S as a sensing unit for detecting a plurality of inspector units as a single unit, as shown in FIG. It is preferable to detect radiation R having a very long wavelength such as a millimeter wavelength or a micro wavelength emitted from the human body at the same time at a plurality of points and measure the intensity and waveform of the radiation R.

The body 1 is made of plastic and has a substantially cylindrical shape. As shown in FIG. 1, the body 1 is provided with a male screw 1a on the outer periphery of the slightly tapered body wall on the one end side, and the body 1 has a converging inside. The chamber 3 is attached integrally.

The cover 2 is a cylindrical body whose one end is open. The cover 2 has a female screw 2a provided on the inner peripheral surface of the open end and is screwed to the male screw 1a of the body 1. It can be installed. Reference numeral 4 denotes a protrusion having a screw hole provided on the outer peripheral surface of the cover 2. The cover 2 is rotated by tightening a screw 5 in the screw hole.
Is fixed to the body 1 at a predetermined position.

The focusing chamber 3 is made of copper and has a bottomed cylindrical shape. The focusing chamber 3 has a diaphragm hole 7 formed at the center of a partition wall 6 forming the bottom. This aperture 7
Is integrally provided with a horn 8 that continuously opens like a trumpet, and the end portion on the side corresponding to the male screw 1a is opened and the expanded end portion of the horn 8 is opened as shown in FIG. The focusing chamber 3 is integrally mounted inside the body 1 by being fixed to the other open end of the body 1.

The sensor S provided at the other end of the cover 2 is provided so as to be connectable to the information control unit 10 via the A / D converter 9. An amplifier (not shown) may be provided in the subsequent stage of the sensor S or the A / D converter 9 in order to amplify the detection amount of the radiation R detected by the sensor S as necessary. . In the figure, the A / D converter 9
Is separately provided between the sensor S and the information control unit 10, but the A / D converter 9 may be integrated into the sensor S or the information control unit 10.

As shown in FIG. 8, for example, the sensor S has a sealed container 20 filled with an inert gas 21 such as argon, and the positive and negative electrodes 22, 2 are filled in the container 20.
There is an ionization chamber type which is provided with a detection unit 24 which is provided so as to face each other. 25 is an external circuit 26 with respect to the electrodes 22 and 23.
Is a power supply unit connected in series with R, and R is a resistor. When the particles of the radiation R emitted from the human body pass through the inert gas 21 enclosed in the container 20, the generated free electrons E and the positive ions I ⁺ have a positive electrode 22 of a negative sign or a negative ion. Immediately moving toward the electrodes 23, respectively, the electrodes 22,
23. Thus, when the free electrons E and the positive ions I ⁺ reach the electrodes 22 and 23 having opposite signs, a small current is generated in the external circuit 26, and the current is detected as a voltage drop in the resistor R.

Further, as another example of the sensor S, as shown in FIGS. 9 and 10, for example, positive and negative electrodes 32, 32 are provided on both sides of a crystalline semiconductor plate material 31 of silicon or germanium having a coating 30 deposited on one side. There is a configuration in which 33 is provided so as to face it. By applying a voltage to the semiconductor plate 31 in a direction that does not guide electricity, when the charged particles of the radiation R emitted from the human body pass through the semiconductor plate 31, free electrons E and positively charged ions I ⁺ are generated. To do. In this way, the generated free electrons E immediately move toward the positively charged surface of the semiconductor plate material 31, while the positively charged ions I ⁺ compose a part of the crystal lattice and thus move freely. This is not possible, but nevertheless the positively charged ions I ⁺ move towards the negative electrode 33. This is because the positively charged ion I ⁺ captures an electron from the neutral atom adjacent to it toward the negative electrode 33, and it is the electron that actually moves, but as a result, the positive ion I ⁺ becomes negative. This is because one step closer to the electrode 33.

A computer (CPU), for example, is used as the information control unit 10, and the information control unit 10 processes the measurement value of the intensity of the radiation R generated from the human body by the sensor S and displays the measurement result of the waveform or the like. To operate a keyboard 38 described later for recording and saving in a storage device such as a semiconductor memory, a magnetic disk, a magnetic tape (not shown), or reading out already recorded intensity measurement values and waveforms. This is for displaying on the display 36 as an external output device or for printing out the recorded contents such as each measurement value on the recording paper by the printer 37. On this occasion,
The information control unit 10 uses a plurality of inspector units A to detect radiations R having a very long wavelength, such as a millimeter wavelength and a micro wavelength, emitted from a human body of a patient at a plurality of locations, and to detect the radiation R.
When the intensity and the waveform of the radiation R are measured and the processing is performed, the measured values and the waveform of the intensity of the radiation R are displayed individually or on a desired plurality of displays 36, or printed out on the printer 37. be able to.

Reference numeral 34 is a signal line routed between the sensor S and the A / D converter 9, and 35 is a signal line routed between the A / D converter 9 and the information control section 10. For the signal lines 34 and 35, for example, optical fibers are used to transfer the measurement information of the radiation R measured by the sensor S quickly and with high density without loss. Signal line 3
It is convenient to use connectors to connect 4, 35 and equipment to each other.

Reference numeral 36 denotes a display as an external output device which is provided so as to be connectable to the information control section 10. The display 36 measures the intensity and waveform of the radiation R from the human body detected by the sensor S. Is displayed and used as a reference material when performing an inspection or treatment.

Similarly, 37 is a printer as an external output device which is provided so as to be connectable to the information control unit 10, and this printer 37 indicates the intensity of the radiation R from the human body stored in the information control unit 10. This is for reading out measurement values and measurement results of waveforms and printing them out on recording paper.

Reference numeral 38 is a keyboard as an external input device that is connectably connected to the information control unit 10.

The length a of the chamber which is adjustable between the partition wall 6 and the sensor S shown in FIG. 1 is rotatably operated by screwing the male screw 1a and the female screw 2a. It is determined by the installation position of the cover 2.

The cover 2 is attached so that when the cover 2 is brought into contact with the body 1 by rotating the cover 2 inward, the installation position of the screw 5 for fixing the cover 2 to the body 1 is zero. ing. Therefore, if necessary, the scale mark 40 and the scale number 41 are displayed on the outer periphery of the end portion of the body 1 in contact with the cover 2 (in the direction in which the screwing depth becomes shallow), when the cover 2 is rotated. The position of the cover 2 at the time of measurement becomes easy to confirm, which is suitable for adjusting the chamber length a due to the change of the attachment position of the focusing chamber 3. At this time, the numeral 41 is set with the screw 5 as a reference point with the position corresponding to the screw 5 set to zero when the cover 2 contacts the body 1, for example. Then, the cover 2 is installed on the outside so that the scale mark 40 and the numeral 41 increase each time the cover 2 rotates by 1/10, for example.

One embodiment of the present invention has the above configuration.
Radiation R having a very long wavelength, such as a millimeter wavelength, emitted from a human body such as a patient is condensed by a horn 8 and passes through a constriction hole 7 provided at substantially the center of the partition wall 6 of the horn 8 to form a focusing chamber 3
It enters inside and is detected by the sensor S.

In order to measure the intensity and the waveform of the radiation R having a very long wavelength generated from the human body, the inspector unit A is moved toward the patient's head as shown by the chain double-dashed line in FIG. In this state, the cover 2 is rotated outward from the zero point position in contact with the body 1. This is because when there is cranial nerve injury or nerve stress, radiation R of a minute length such as millimeter wavelength or micro wavelength is emitted while forming a radial portion around it, so the whole body is the main nerve center that communicates with the cranial nerve. The nerve bundle CNC (Critical) with a diameter of about 1 mm or less scattered about 50 to 60 points in the
Nerve Center) is to detect radiation R continuously by the inspection unit A for each predetermined site in a predetermined procedure and continuously measure it to find the nerve stress center as a pathological site with dysfunction. is there.

When the sensor S detects the radiation R, the detected amount is converted from an analog signal to a digital signal by the A / D converter 9. Then, this digital signal is processed by the information control unit 10 connected to the A / D converter 9, and the measured value is recorded. Since the detected amount of the radiation R is digitized and measured in this way, the radiation R is a radiation R having a millimeter wavelength or a waveform such as a micro wavelength, and even when the radiation amount is a very small amount, It is possible to reliably detect the intensity of R. Further, since the radiation R can be measured with high accuracy and in a wide band, it is not limited to the case of mere illness or dysfunction,
More precise than that, such as endocrine system, nervous system,
Also in the immune system, cancer system, etc., the radiation R can be continuously measured to identify the pathogenic part.

Furthermore, since the information control unit 10 is provided with an external output device such as the display 36 and the printer 37 which can be connected, the intensity and waveform of the radiation R can be controlled by operating the external input device such as the keyboard 38. It is possible to immediately display the measurement result of (3) on the screen of the display 36, or to immediately read out the record of each measurement value of radiation intensity and the waveform stored in the information control unit 10 and print it out on the recording paper by the printer 37. it can. Therefore, the inspector can perform measurement and inspection while objectively grasping the measured value of the radiation R of the patient or the like.

The tester unit A of the present invention also has a feedback function to eliminate or reduce the radiation R generated from the cranial nerve injury or the nerve stress portion.
That is, the inspector unit A is fixed to an arm of a stand (not shown), the radiation R is measured toward the patient's nerve stress center as described above, and the other finger gently touches the nerve stress center. Treatment is performed by pressing and applying pressure, etc. until the radiation that is sensed disappears. If this treatment is complete, the patient's nerve tissue will recover to a healthy state, and a minute length of radiation R such as millimeter wavelength or micro wavelength will be emitted from the patient until the neuropathy or nerve stress recurs. Will not be done. Therefore, no radiation is detected by the inspector unit A.

Further, the left and right temporal regions of the patient are referred to as TS lines as shown in FIG. 7, for example, along the nervous system along muscles, internal organs, organs, and the butterfly-shaped temporal suture line of vertebra and skull. When measuring the radiation R at several tens of points
Instead of individually measuring and inspecting the radiation R for each temporal region of the patient using the individual inspector units A,
By simultaneously bringing the two inspector units A close to the left and right temporal regions of the patient, the radiation R can be measured at two points at the same time. Therefore, the measurement time can be shortened and the treatment can be performed efficiently.

Table 1 below shows each of several tens of points a to y on the butterfly-shaped temporal suture line of the skull called the TS line.
This is a systematic summary of the relationships between points a to b, the muscles of the relevant body parts, and the internal organs and organs.

[Table 1]

Further, there is no dysfunction of the cranial nerve tissue, and the radiation R of a minute length such as a millimeter wavelength is not emitted from the brain.
Radiation R is emitted from other parts other than the brain, such as the spine (cervical vertebrae, thoracic vertebrae, lumbar vertebrae), arm parts, leg parts, and if there is a functional disorder or disease in the visceral parts or organs, the part or its peripheral parts Has been done. Therefore, the inspection unit A
Using the to trace the CNC of the nervous system leading to the cranial nerve, and tracing the points a to r on the TS line shown in FIG. 7 and the muscle parts and organs shown in Table 1 above, in accordance with a predetermined procedure for each predetermined part. By continuously measuring the radiation R, the central part of the nerve stress as a pathogenic part having a functional disorder is inspected, but in this case, as shown in FIG. By measuring the intensity and waveform of the radiation R generated at a plurality of places and displaying them individually or at a plurality of places on an external output device such as the display 36, it is possible to instantly detect pathogenic parts with functional disorders such as internal organs and organs. It is possible to clearly determine whether or not it can be identified and which part should be improved by applying the correction treatment, and objective measurement can be performed.

At this time, in the radiation inspecting apparatus of the present invention, the radiation R emitted from the human body is detected by the sensor S, and the analog signal is converted into a digital signal by the A / D converter 9 connected to the sensor S. Therefore, even when the amount of radiation from the human body is very small, it is possible to reliably detect the measurement result of the intensity or waveform of the radiation R. Further, the radiation R is not limited to the millimeter wavelength, and even the radiation R having a very long wavelength of a micro wavelength can be detected and measured by the sensor S. Moreover, the radiation R in a wide band can be measured. Furthermore, the inspector displays the measured values and waveforms of the intensity of the radiation R individually or at a plurality of locations based on the display contents of the display 36 connected to the information control unit 10 and the records output to the printer 37 and compares them with each other. By doing so, measurement and inspection can be performed while objectively grasping. For this reason, endocrine diameter, nervous system, immune system, which requires highly accurate measurement and inspection,
It is possible to measure the intensity and the waveform of the radiation R related to the cancer system and the like.

If, for example, the patient has numbness in his right hand due to an analog signal, the radiation R generated from the patient is measured by first measuring the exit point of the brachial nerve, that is, the cervical vertebra part, then the brachial part, and the elbow. It is necessary to measure the generated radiation R while applying pressure (stress) while moving one by one to the body part, the wrist part, and the finger part. Therefore, it took a lot of time and labor for the measurement. The digital processing of the signal saves a short measurement time. Moreover, conventionally, the radiation R generated from each part of the body is greatly influenced by the experience and intuition of the inspector, and the detection is also sensuous. Furthermore, the intensity of the radiation R and its waveform cannot be detected. There wasn't.

Further, in the radiation inspection apparatus of the present invention, the sensor S is A / D via the signal line 34 such as an optical fiber.
Since the A / D converter 9 is connected to the information controller 10 via the signal line 35 such as an optical fiber, the A / D converter 9 converts the analog signal into a digital signal. A large number of measured values of the radiation R that are converted and detected by the sensor S for each part of the body can be transferred to the information control unit 10 at high density, and a large amount of information regarding the measured values is accumulated in the information control unit 10. Therefore, there is an advantage that the data can be processed at high speed and the information once stored in the information control unit 10 can be read and reused.

[0039]

As described above, according to the present invention, the radiation emitted from the human body is detected by the sensor, and the detected amount is converted from analog to digital and transferred to the information control unit. The inconvenience of the inspection device can be solved, and the intensity and waveform of the radiation having a very long wavelength can be detected with high precision and the position of the nerve stress center can be properly found. Therefore, by continuously observing the central portion of the nerve stress until the functional disorder disappears, the nerve disorder can be properly restored to normal and the functions of various parts of the human body can be normalized.

Further, according to the present invention, information control is performed by measuring the intensity or waveform of radiation of a very long wavelength such as millimeter wavelength or micro wavelength emitted from a human body by using a plurality of inspector units individually or at a plurality of locations. Since it can be processed and stored in the department, it is possible to comprehensively and objectively perform high-precision measurement, inspection, and treatment while comparing these measurement results with each other.

[Brief description of drawings]

FIG. 1 is a cross-sectional view showing an embodiment of a digital radiographic inspection device of the present invention.

FIG. 2 is likewise a perspective view of the present embodiment.

FIG. 3 is likewise a front view of this embodiment.

FIG. 4 is a right side view of the same embodiment.

FIG. 5 is a left side view of the same embodiment.

FIG. 6 is an explanatory front view showing another mode of use of this embodiment.

FIG. 7: TS also as a butterfly-shaped temporal suture line of the skull
It is an explanatory side view showing each measurement point drawn on a line.

FIG. 8 is a cross-sectional circuit diagram showing an example of a sensor that constitutes this embodiment.

FIG. 9 is a cross-sectional view showing another example of the sensor which constitutes this embodiment.

10 is an operation diagram of the sensor shown in FIG.

[Explanation of symbols]

 1 body 1a male screw 2 cover 3 focusing chamber 5 screw 6 partition wall 7 throttling hole 8 horn 9 A / D converter 10 information control unit 36 display 37 printer 38 keyboard A inspection unit

Claims (9)

[Claims] 1. A digital system comprising an inspector unit, a sensor which is combined with the inspector unit and measures the intensity and waveform of radiation, and an information control unit which digitally processes a signal detected by the sensor. Radiation inspection device. 2. The inspector unit comprises a substantially cylindrical body, a cover rotatably screwed into a body wall at one end of the body and provided with the sensor on one side, and the cover side is opened. It has a bottomed cylindrical horn that expands outward from a throttle hole provided in the center of the partition wall, and a focusing chamber installed in the body so as to open the horn to the other end of the body. 2. The digital radiological inspection apparatus according to claim 1, wherein the radiation intensity and the waveform are formed by measuring a length of a chamber formed between the aperture and the sensor. 3. The digital system according to claim 1, wherein radiation is detected at a plurality of locations at the same time by using a plurality of the inspector units, and the intensity and the waveform of the radiation are measured. Radiation inspection device. 4. The digital radiation inspector according to claim 1, wherein the sensor is provided so as to be connectable to an information control unit via an A / D converter. 5. The detection unit, wherein the sensor has positive and negative electrodes facing each other in a hermetically sealed container in which an inert gas such as argon is sealed, and a radiation particle can pass between the two electrodes in a crossing direction. 5. A digital radiological inspection apparatus according to claim 1, 2 or 4, wherein the ionization chamber is provided with an ionization chamber. 6. The dipole tube having positive and negative electrodes facing each other on both sides of a crystalline semiconductor plate material of silicon or germanium having an insulating coating film on one side, the sensor being a bipolar tube exhibiting electrical conductivity in one direction. 5. The digital radiological inspection apparatus according to claim 1, 2 or 4, wherein the structure is of a semiconductor type. 7. The digital radiographic inspection apparatus according to claim 1, wherein the signal line routed between the sensor and the information control unit is an optical fiber. 8. A measurement value or a waveform of the intensity of radiation detected by the sensor is converted from an analog signal to a digital signal by the A / D converter,
The digital signal is stored in the information control section so as to be recordable and readable.
Alternatively, the digital radiographic inspection device according to claim 4. 9. The information control unit is connected to an external input device such as a keyboard, and an external output device such as a display or a printer for displaying measured values or waveforms of radiation intensity individually or at desired plural places. The digital radiographic inspection device according to claim 1 or 4, wherein the digital radiographic inspection device is connected to the information control unit.