KR101690464B1 - Safety administration system for industries based on biorhythm - Google Patents

Abstract

The present invention provides an industrial safety management system based on a biorhythm, to detect a biorhythm and provide a suitable working environment according to business intensity based on the detected biorhythm, so as to prevent occurrence of an accident. To this end, the industrial safety management system comprises: a biometric signal detection apparatus to detect a signal of a person to be examined, and to digitalize and output the detected biometric signal; and a biorhythm detection apparatus to calculate a biorhythm including a physical rhythm, an emotional rhythm, and an intelligent rhythm based on digitalized data outputted from the biometric signal detection apparatus, and to determine and display a high period and a low period with respect to each rhythm. The biometric signal includes a voice signal, a blood pressure, a pulse, a brainwave, an electrocardiogram, a body heat, a physical index, and muscle strength.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a safety management system for a biorhythm-based industrial field,

The present invention relates to a biorhythm-based industrial field safety management system, and more particularly, to a biorhythm-based industrial field safety management system that detects a biorhythm and provides an appropriate working environment according to the intensity of a biorhythm based on the detected biorhythm, Based safety management system based on biorhythm.

Biorhythm is the theory that there are three cycles of body, sensibility, and intelligence in the human body, and these three cycles appear as specific patterns according to the date of birth, and there is a difference in ability and activity efficiency depending on the combination of these patterns. This biorhythm is called a biological cycle, or, in general, a biological clock, a body clock, or the like. The biorhythm is classified into three types of physical rhythm, sensitivity rhythm and intellectual rhythm. The body rhythm is 23 days, emotional rhythm is 28 days, and intellectual rhythm is 33 days , And has been reported to exhibit a change in rise or fall.

In the 19th century, the biorhythm claimed that Wilhelm Fleisch, a physician of the earliest studies of fever disease, had a cycle of 23 days and 28 days in the human body. After that, Alfred Telther studied his students and claimed the 33- .

Body rhythm is a rhythm that represents the physical state of the body. It is used as a measure to gauge the immunity to the disease, the function of various internal organs, and the reflex of the body to the external environment. Emotional rhythm is a rhythm that expresses the state of the mood or the nervous system, and represents creativity, interpersonal relationships, emotional ups and downs. The intellectual rhythm is a rhythm that represents the ups and downs of concentration, memorization memory, logical thinking ability, analytical discrimination power, and rhythm mainly related to brain activity.

A typical biorhythm is calculated according to the date of birth. The formula for calculating the biorhythm according to the date of birth is body rhythm: sin (2πt / 23), emotional rhythm: sin (2πt / 28), and intellectual rhythm: sin (2πt / Where t is the number of days from birth to the day of calculation.

However, the individual's biorhythm can be greatly influenced by factors such as the environment in which the individual grows and lives, and it is difficult to determine the individual's biorhythm based on the date of birth. When the biorhythm calculated based on the date of birth is actually calculated, it often occurs that the biorhythm does not match the state of the current examinee (subject).

On the other hand, biorhythm is used in many fields. For example, many studies have been conducted to apply biorhythm related to transportation, railway accidents, traffic accidents and safety work.

As one of techniques for applying the biorhythm to a work site, a management object health management system and a management method thereof are disclosed in Patent Publication No. 10-1576500 through the emotional safety culture of the workplace.

The present invention relates to a health monitoring system, a health monitoring system, a health monitoring system, a health monitoring system, and a health monitoring system, And an output terminal connected to the health management server via a network for displaying the health status information and the health diagnosis information of the management subject received from the health management server, And a control unit.

However, the above-described technique does not describe a specific means for detecting a biorhythm, and when it is determined that the value of the health diagnostic information including the biorhythm is less than the set value, the user can solve the problem through the game, A problem occurs.

KR 10-1576500 B1 (December 04, 2015)

Disclosure of Invention Technical Problem [8] The present invention has been made in order to solve the problems of the prior art, and it is an object of the present invention to provide a biorhythm detection system, Which can prevent the occurrence of the biorhythm-based safety management system.

Another problem to be solved by the present invention is to provide a biorhythm-based industrial field safety management system capable of discriminating body rhythms, emotional rhythms, and intellectual rhythms based on detected bio-signal data.

In order to solve the above problems, a biorhythm-based industrial site safety management system according to the present invention includes a bio-signal detection device for detecting a bio-signal of a to-be-inspected person, digitizing and outputting the detected bio-signal; And a biorhythm detecting device for calculating a biorhythm composed of a body rhythm, an emotional rhythm and an intellectual rhythm on the basis of the numerical data output from the bio-signal detecting device, and judging and displaying the high and low tones for each rhythm And the bio-signal includes a voice signal, a blood pressure, a pulse rate, an electroencephalogram, an electrocardiogram, a body temperature, a body index and a muscle force.

Here, an acoustic device may be further included in which predetermined music corresponding to the calculated biorhythm is output.

Here, the sound apparatuses are classified into major categories according to age, middle classes according to gender, and then classified into a tempo, and music is stored and managed. A sound controller for searching for music corresponding to the biorhythm in the memory and outputting the music; And a speaker for outputting music according to the control of the sound control unit.

The bio-signal detection apparatus may further include: a voice detector for detecting voice; A blood pressure meter for measuring blood pressure and pulse; An EEG signal detector for detecting an EEG; An electrocardiogram that measures current by inducing the action currents generated by the myocardium according to the heartbeat to the body surface; A thermometer for detecting body temperature; A physical index measuring device for measuring a body index by measuring height and weight; And a muscle strength measuring device for measuring the muscle strength.

The biorhythm detecting apparatus may further include a rhythm calculating unit that receives the numerical data output from the bio-signal detecting apparatus, and calculates a biorhythm based on the received numerical data as a body rhythm, an emotional rhythm, and an intellectual rhythm; A determination unit for determining a high level and a low level for each rhythm calculated by the rhythm calculation unit; An input unit for receiving personal information of the person to be inspected; A display unit for displaying a result of the determination by the determination unit in a graph; A storage unit for storing and managing the personal information input from the input unit, the bio-signals corresponding to the personal information, and the calculated biorhythm; And a communication unit for performing communication with an external device.

The biorhythm-based industrial field safety management system according to the present invention improves the reliability of the detected biorhythm by detecting the biorhythm based on the biological signal, and can arrange the workers based on the resultant value and the intensity of the task It is possible to minimize the occurrence of safety accidents and to improve work efficiency.

In addition, detecting the bodily rhythm, emotional rhythm, and intellectual rhythm of the biorhythm based on the bio-signal value can shorten the time required for detecting the biorhythm, and can arrange tasks by rhythm.

1 is a graph showing a cycle of a biorhythm;
FIG. 2 is a schematic diagram of a biorhythm-based industrial field safety management system according to the present invention. FIG.
3 is a block diagram of a biological signal detection apparatus applied to a safety management system for industrial sites based on a biorhythm according to the present invention.
FIG. 4 is a table showing calculation parameters and ratios of biorhythm applied to a safety management system for a biorhythm-based industrial field according to the present invention.
FIG. 5 is a block diagram of music stored in a memory of a sound device applied to a safety management system for industrial sites based on a biorhythm according to the present invention. FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The present invention provides a biorhythm-based industrial site safety management system capable of detecting a biorhythm and providing an appropriate work environment according to the intensity of work based on the detected biorhythm to prevent the occurrence of a safety accident.

1 is a graph showing a cycle of a biorhythm.

Referring to FIG. 1, the biorhythm has a physical rhythm of 23 days, a sensory rhythm of 28 days, and an intellectual rhythm of 33 days. The three rhythms (body rhythm, emotional rhythm, and intellectual rhythm) are derived as gentle sine curves composed of the high period of the first half and the low period of the second half.

The biorhythm is derived as a sine curve, which is a kind of trigonometric function, but the shape of the graph is slightly different because the three rhythmic cycles are different. If the sine curve is on the horizontal axis, the condition is good, and if it is below, it is stagnated.

It is a dangerous thing when the sign curve meets the horizontal axis. The precarious work is not the lowest point but the unstable point where the rhythm of body, emotion, and intelligence changes. In other words, the day when each rhythm transitions from the low or early to the high rhythm in which the rhythm crosses in the horizontal axis is converted into the rhythmic nature, so the mind and the mind become unstable and the risk becomes latent.

FIG. 2 is a schematic diagram of a biorhythm-based industrial field safety management system according to the present invention.

2, a biorhythm-based industrial site safety management system according to the present invention may include a bio-signal detection device 100, a biorhythm detection device 200, and a sound device 300.

The living body signal detecting apparatus 100 detects a living body signal of a person to be inspected (e.g., a worker), digitizes and outputs the detected living body signal, and the living body signal to be detected includes a voice signal, a blood pressure, , Electrocardiogram, body temperature, body index and muscle strength.

FIG. 3 is a diagram illustrating a configuration of a bio-signal detection apparatus 100 applied to a safety management system for a biorhythm-based industrial field according to the present invention.

3, the bio-signal detection apparatus 100 includes a voice detector 110 for detecting voice, a blood pressure meter 120 for measuring a blood pressure and a pulse, an EEG signal detector 130 for detecting an EEG, , An electrocardiogram (140) for measuring current by inducing an activity current generated in the myocardium according to the heartbeat to the body surface, a thermometer (150) for detecting the body temperature, a body index meter for measuring the body index by measuring the height and weight, (160) and a muscle strength meter (170) for measuring muscle strength.

The voice detector 110 is a device that receives a sound wave or an ultrasonic wave and generates an electric signal corresponding to the vibration, and receives the voice of the person to be inspected (subject). At this time, the voice may be detected by inducing the examinee to read a predetermined word or sentence, and may be composed of a microphone or the like. In addition, the voice may consist of a signal that lasts for a predetermined time.

Accordingly, the voice input to the microphone may be output as a waveform and output as an average value of the output waveform.

Here, the average output value for the speech may be configured to be output in dB, and may be configured to be detected from a minimum of 40 dB to a maximum of 80 dB.

The voice is directly or indirectly associated with the biorhythm. In other words, the body rhythm, emotional rhythm, and intellectual rhythm tend to be different in the waveform of the voice detected according to the high and low periods. For example, in each rhythm treble, the sound is detected in excess of 60 dB, and conversely in the low tone is output in less than 60 dB.

The blood pressure measuring device 120 detects the pulse pressure according to the pressure and detects the pulse rate per minute in the process of pressing and relaxing the arm or the ankle of the examinee. The blood pressure measuring device 120 provides compressed air for blood pressure measurement, A pressure cuff which expands by the compressed air from the blood pressure gauge and presses the body of the patient, and the compressed air from the blood pressure cuff is transmitted to the blood pressure monitor And a pulse signal measurement module for processing a sensing signal from a magnetic element having a magnet-impedance characteristic, which is installed in the pressing bar, into an electric signal for pulse measurement.

The EEG signal detector 130 detects an EEG signal of an examinee and includes an input module for converting input fine voltage into a current signal and outputting the current signal, an output module for converting the current output from the input module into a voltage, A module, and a DC servo loop for removing the offset of the input module.

At this time, EEG can be detected as alpha, beta, cetaph, and delta waves.

Alpha waves are the most common waveforms in EEG, 8 to 12 times per second, and are mental stabilized when they are in a quiet environment. Both governments appear predominant in the occipital lobe.

Beta waves are irregular and are output 18-24 times per second, and are output when the nervous system is active or in an excited state. Prefrontal, preponderant in temporal lobe,

Theta waves are output four to seven times a second, which occurs when the brain is in a state of emotional state expression. There is a feature that does not appear well under normal conditions.

Delta waves are output in about 0.3 to 3.5 seconds at about 4 times, and the amplitude at sleep is large and slow.

The electrocardiogram 140 measures current by inducing an activity current generated in the myocardium according to the heartbeat to the body surface.

Electrocardiogram (ECG) is an electrocardiogram (ECG) that detects and records the activity current in the myocardium as an electrical signal on the body surface. It is a unit ECG consisting of P wave, QRS group (Q wave, R wave, S wave) Is regularly shown by the magnetic excitability of cardiac cells. In the unit ECG, there is a gap called a segmentation interval starting from the T wave end point of the front end unit electrocardiogram to the starting point of the P wave of the subsequent unit electrocardiogram, and U wave appears in this section, (Q wave, R wave, S wave) and a characteristic point and a PR interval (PR interval) extracted from a T wave are generally used to identify an arrhythmia.

The P wave is a waveform that appears first when electrical activity of the heart begins and is positive (upper) small acid. The P wave signifies electrical excitation of the atria. Precisely, the right atrium starts to be excited and the next left is excited, which appears as one waveform in normal electrocardiogram. The normal P wave has a width of 0.09 to 0.11 second and a height of 2.5 mm or less.

The P wave passes and a small motion in the voice (downward) is seen. This wave is called "Q wave". Then, the "R wave" appears with a high and sharp positive motion, and the R wave quickly returns to the base line and transits to the voice movement again, which is called "S wave". This Q wave, R wave, and S wave are not falling but always appear as one motion, so they are integrated into the "QRS group". The normal range of QRS is 0.04 to 0.11 seconds.

The P-R interval (PR interval) is the time from the beginning of the P wave to the beginning of the QRS complex, which is the atrial-ventricular muscle stimulation conduction time. In other words, it is the conduction time from the SA node to the AV node, and the normal range is 0.12 to 0.2 second.

The T wave is the repolarization time of the ventricle and the normal range is within 0.16 seconds.

The electrocardiogram 140 for performing such a function includes an electrode module for electrocardiogram measurement for measuring an activity potential in contact with the skin and a control module for processing a signal (electrocardiogram signal, active current) detected by the electrode module, do.

The thermometer 150 detects the body temperature of the examinee, and may be selected from various types such as a mercury thermometer, an electronic thermometer, a patch type thermometer, or an infrared thermometer. Among them, an infrared thermometer capable of measuring the body temperature relatively easily in a short period of time can be adopted. The infrared thermometer includes an infrared lamp and a sensor for sensing the infrared lamp. The infrared thermometer includes an ear thermometer and a forehead thermometer, depending on the part to be measured.

The body index measuring unit 160 measures height and weight of a subject to be examined, and may include an extensometer for measuring height, a body scale for measuring body weight, and a body fat measurement unit for measuring body fat.

The muscle strength measuring device 170 may be configured to measure upper and lower body strengths and may be configured to detect muscle power, muscle endurance, or flexibility.

Muscle strength can be involved in calculating body rhythms. For example, if the muscle strength is relatively lower than usual, it can be judged that the body rhythm belongs to the early period.

As described above, the living body signal detecting apparatus 100 detects the voice, the blood pressure, the electrocardiogram, the body temperature, and the body index of the examinee (subject) and outputs the detected data as a numerical value.

At this time, the numerical data of body temperature, blood pressure, and pulse rate can be outputted as a grade according to the deviation from the general average value.

For example, in the case of body temperature, ± 1% at normal body temperature (36.5 ° C) may be determined as fifth grade, ± 1 to ± 2% as fourth grade, and ± 2 to ± 3% as third grade.

In addition, the blood pressure can be determined in the order of 5, 10, 15, and 15% of the blood pressure based on the systolic phase of 110 mmHg, and 4 to 10% to 15% Can be applied. The pulse rate is regarded as the normal pulse rate per minute from 50 to 100 times. Therefore, ± 20% is determined as 5, ± 20 to ± 30% as 4, and ± 30 to ± 35 as 3 .

The biorhythm detecting apparatus 200 calculates the body rhythm, the emotional rhythm, and the intellectual rhythm based on the numerical data output from the bio-signal detecting apparatus 100, and judges and displays the high and low tones for the rhythm, respectively .

2, the biorhythm detecting apparatus 200 includes a rhythm calculating unit 210, a determining unit 220, an input unit 230, a display unit 240, a storage unit 250, and a communication unit 260. [ .

The rhythm calculating unit 210 receives the numerical data output from the bio-signal detecting apparatus 100 and calculates biorhythm, that is, body rhythm, emotional rhythm, and intellectual rhythm based on the received numerical data .

At this time, parameters for calculating the biorhythm (body rhythm, emotional rhythm, and intellectual rhythm) are configured differently. In addition, the ratio of the parameters is also different according to the rhythm.

4 is a table showing calculation parameters and ratios of biorhythm applied to a safety management system for a biorhythm-based industrial field according to the present invention.

Referring to FIG. 4, the parameters for calculating the body rhythm are body temperature, body index, blood pressure, and strength data, and the respective percentages are body temperature 40%, body index 30%, blood pressure 20% . ≪ / RTI > The parameters for calculating emotional rhythm consist of blood pressure, brain waves, voice and electrocardiogram data, and each ratio can be calculated as blood pressure 40%, brain waves 30%, voice 20% and electrocardiogram 10%. In addition, the parameters for calculating the intellectual rhythm can be composed of brain waves, voice, blood pressure and electrocardiogram data, and each ratio can be calculated as 40% of EEG, 30% of voice, 20% of blood pressure and 10% of ECG.

Here, each rhythm may be configured to be calculated based on a maximum value of 100. For example, among the parameters for calculating body rhythm, 40 points belonging to the normal range are given to the body temperature, and the values are subtracted as the grade is lowered. The remaining body index, blood pressure and muscle strength also score 30 points, 20 points and 10 points, and it can be configured so as to be subtracted as the distance from the normal range increases.

In other words, the lowest value of the early phase may be set to 0, and the maximum value of the higher harmonics may be set to 100, so that the calculated value of the body rhythm, emotional rhythm and oyster rhythm may have a value between 0 and 100.

The determination unit 220 determines the high and low tones for each of the rhythms calculated by the rhythm calculation unit 210.

At this time, since the high and low phases are in a symmetrical relationship with each other in the form of sine waves, when the calculated value 50 is 50 or more, the high and low phases are judged.

Here, the high and low stages can be classified into a rising state and a falling state. That is, even if the determined rhythm is a treble, it can not be judged by a single measurement whether it is a treble in the ascending state or a treble in the descending state.

Accordingly, the determination unit 220 may be configured to determine a high level of the rising level or a rising level of the rising level based on the previously stored data.

In other words, when the current state is determined to be a high level, the higher level is determined to be higher than the calculated value of the previously stored data, and the higher level is determined to be the rising level.

In addition, if the current state is determined to be low, it is determined to be the low state of the rising state if it is relatively higher than the calculated value of the previously stored data, and otherwise, it is determined to be the low state of the falling state.

Here, the determination unit 220 may be configured to determine that it is a dangerous event when switching from a low or high to a high level in the high level.

If there is no previous data, it is determined that the calculated value is judged to be a dangerous day if the calculated value is within a range of ± 2 to 5% of 50.

The input unit 230 is for inputting or modifying personal information of the examinee (subject), and may be constituted by a mouse keypad or the like. At this time, the person to be inspected can be configured to be managed by an identification number such as an ID or a number.

Here, the personal information may include an age (date of birth), a sex, an address, a telephone number, a job, a position, a position, and the like of the examinee (subject).

The display unit 240 displays a result of the determination by the determination unit 220 in a graph.

At this time, the graph displayed on the display unit 240 is displayed in the form of a sine wave of body rhythm, emotional rhythm, and intellectual rhythm, and the presently measured position is displayed. When the determination unit 220 determines If so, display it.

The storage unit 250 stores and manages bio-signals corresponding to personal information and the calculated biorhythm. That is, the personal information of the examinee (subject) inputted through the input unit 230 and the calculated biorhythm corresponding to the detected biometric signal corresponding to the personal information are stored and managed. Here, time information is included in the stored information (personal information, biometric signal data, biorhythm, etc.).

The communication unit 260 is for communicating with an external device and is for transmitting information stored in the storage unit 250 to an external device or receiving a control signal from an external device. At this time, the external device may be configured as a management server for managing the biorhythm-based industrial field safety management system of the present invention or a portable terminal for controlling the biorhythm-based industrial field.

On the other hand, if it is determined that the specific rhythm of the biorhythm is low or dangerous as a result of the determination by the determination unit 220, the examinee (subject) may be appropriately disposed according to the intensity of the task. For example, in the case of an employee engaged in the transportation industry, the worker can be configured to dispatch to a short-distance operation with a relatively short operating time rather than to a long-distance operation. In the case of an alternate worker, the shift time can be shortened and operated.

However, as in the above example, if there is an alternative to adjust the work intensity by flexibly arranging the workers according to the results of the biorhythm, safety accidents can be prevented in advance, but substitute workers In case of absence, a way to improve it through the result of biorhythm should be sought.

Accordingly, in the present invention, the result of biorhythm can be improved through music, so that the sound device 300 can be configured.

The sound device 300 is configured to output predetermined music corresponding to the calculated biorhythm. The sound device 300 includes a memory in which music is stored for each rhythm and a genre, a predetermined music corresponding to the biorhythm is retrieved from the memory, And a speaker (such as earphone or headset) for outputting music according to the control of the sound control unit.

The rhythmic pattern of melody inherent in music has been used as a means of alleviating physical fatigue and has been reported to affect blood circulation, heart rate as well as respiration, and changes in pulse rate and blood pressure. For example, research has shown that music stimulates pulsation, affects the heart, circulatory system, digestive system and respiratory system, calms feelings of anger and hatred, and relieves stress.

Here, the negative pitch (tempo) is a major factor in causing a physiological response, a fast tempo induces tension, and a slow tempo relaxes.

Also, there is music that is preferred according to age and sex.

Accordingly, in the present invention, the music stored in the memory can be divided and stored according to age, gender, fast tempo, and slow tempo.

FIG. 5 illustrates the structure of music stored in a memory of a sound device applied to a safety management system for a biorhythm-based industrial field according to the present invention.

Referring to FIG. 5, music stored in the memory is classified into age groups (20 to 50), classified into gender, and then classified into a tempo and stored and managed. According to the design conditions, the music may include natural music such as water sounds, wind sounds, and rain sounds.

In the process of selecting music in this configuration, when the subject (subject) is a thirties woman and the sensory rhythm is determined to be low (or a dangerous day), the sound control unit of the sound device 300 has 30 - female - can be configured to selectively output one or more of music stored at a slow tempo.

At this time, the selected music may be randomly selected, and may be configured to be changeable according to a user's operation.

According to the biorhythm-based industrial field safety management system according to the present invention, the reliability of the biorhythm detected by detecting the biorhythm based on the biological signals is improved, and the workers can be arranged based on the resultant value and the intensity of the task Therefore, it is possible to minimize the occurrence of safety accidents and to improve work efficiency.

In addition, detecting the bodily rhythm, emotional rhythm, and intellectual rhythm of the biorhythm based on the bio-signal value can shorten the time required to detect the biorhythm, arrange the worker for each rhythm, The biorhythm of the early period is relaxed, and the biorhythm of the high period is induced to induce the tension.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

100: biological signal detection device 110: voice detector
120: blood pressure monitor 130: brain wave signal detector
140: electrocardiogram 150: thermometer
160: body index measuring instrument 170: muscle strength measuring instrument
200: Biorhythm detecting apparatus 210: Rhythm calculating section
220: determination unit 230: input unit
240: display unit 250: storage unit
260: communication unit 300: sound device

Claims (5)

A living body signal detecting device for detecting a living body signal of a person to be inspected, digitizing and outputting the detected living body signal;
A biorhythm detecting device for calculating a biorhythm composed of a body rhythm, an emotional rhythm, and an intellectual rhythm on the basis of the digitized data output from the bio-signal detecting device, and judging and displaying the high and low tones for each rhythm; And
An acoustic device for outputting predetermined music corresponding to the calculated biorhythm;
And,
The bio-
Voice signal, blood pressure, pulse rate, brain waves, electrocardiogram, body temperature, physical index and muscle strength,
The living body signal detecting apparatus includes:
A voice detector for receiving a sound wave or ultrasonic waves for a predetermined word or sentence with a microphone to generate an electric signal for vibration and outputting an average output value for the voice in dB;
A blood pressure monitor comprising: a sphygmomanometer for supplying compressed air for blood pressure measurement and measuring a blood pressure by sensing a change in pressure of the supplied compressed air; a pushing member that is inflated by the compressed air from the sphygmomanometer to urge the body, A blood pressure meter cable for transmitting a blood pressure signal to a blood pressure monitor, and a pulse signal measurement module installed on the pushing pad for processing a sensing signal from a magnetic impedance element into an electric signal for pulse measurement, the blood pressure meter measuring blood pressure and pulse;
An EEG signal detector for detecting an EEG;
An electrode module for measuring an electrocardiogram measuring an activity potential in contact with the skin, and a control module for processing a signal detected by the electrode module for ECG measurement, wherein an action current generated in the myocardium according to the heartbeat is induced to the body surface Electrocardiogram measuring by current;
An infrared thermometer for detecting an infrared ray lamp and an infrared ray lamp; and an infrared thermometer for detecting the temperature of the infrared ray lamp, comprising a sensor for detecting the infrared ray lamp and an ear thermometer or a forehead thermometer,
A body index measuring device for detecting a body index including an extensor measuring a kidney, a body scale for measuring body weight, and a body fat meter for measuring body fat; And
A muscle strength measuring device for detecting muscle strength, muscle endurance and flexibility;
And,
The biorhythm detecting apparatus comprises:
A rhythm calculating unit for receiving the numerical data output from the bio-signal detecting apparatus and calculating the biorhythm based on the received numerical data as a body rhythm, an emotional rhythm and an intelligent rhythm;
A determination unit configured to determine the high and low periods for each rhythm calculated by the rhythm calculation unit and to determine that the period is a dangerous period when the high period is changed from a low period or a low period to a high period;
An input unit for receiving personal information including an age, a sex, an address, a telephone number, a job, a position and a position of the examinee;
A display unit for displaying a result of the determination by the determination unit in a graph;
A storage unit for storing and managing the personal information input from the input unit, the bio-signals corresponding to the personal information, and the calculated biorhythm; And
A communication unit for performing communication with an external device;
And,
In the acoustic device,
A memory in which music is stored and managed by classifying music by gender, classifying music by tempo, and storing music;
A sound controller for searching for music corresponding to the biorhythm in the memory and outputting the music; And
A speaker for outputting music according to the control of the sound control unit;
Lt; / RTI >
The body rhythm is calculated as a parameter consisting of body temperature 40%, body index 30%, blood pressure 20% and muscle strength 10%
The emotional rhythm is calculated as a parameter composed of 40% of blood pressure, 30% of EEG, 20% of voice and 10% of ECG,
The osteoarthritic rhythm is calculated as a parameter composed of 40% of EEG, 30% of voice, 20% of blood pressure and 10% of electrocardiogram,
Each of the body rhythms, emotional rhythms, and oyster rhythms is calculated on the basis of a maximum value of 100. When the calculated value is 50 or more, it is determined that the body rhythm, the emotional rhythm, and the oily rhythm are low.
The elevator and the elevator are classified into a rising state and a falling state, wherein the rising state and the falling state are determined based on the previously stored data,
Wherein if the specific rhythm is determined to be low or dangerous in the biorhythm, the person to be inspected is arranged according to the intensity of work.
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