KR20090112299A - Drunkometer - Google Patents

Abstract

PURPOSE: A drunkometer is provided to measure expiratory flow and easily exposure illegal behavior of a person which is test for drinking. CONSTITUTION: A drunkometer comprises: a housing containing an alcohol sensor(5); a blowing tool(15) which a person to be tested for drinking blows; a display(20) which is installed at the front of the housing; a microphone(35) which is installed at the aerobic path(25); and an amplifier(40) which amplifies electric signal of the microphone and outputs the signal.

Description

Breathalyzer {Drunkometer}

The present invention relates to a breathalyzer, and more specifically, to calculate the amount of exhalation by extracting the sound wave signals generated by the exhalation, and to warn if the calculated exhalation amount is less than the standard value to detect the illegal exhalation behavior of the subject It's about a breathalyzer.

Breathalyzer is a device to determine the blood alcohol concentration of the subject by taking the breath of the subject and measuring the amount of alcohol contained in the breath. The amount of alcohol is measured by an alcohol sensor installed in the breath passage in the breathalyzer. To accurately measure the amount of alcohol, the amount of breath above the reference value must be introduced into the breath passage. Often, however, the subject avoids accurate drinking measurements, either by breathing in or breathing weakly to lower blood alcohol levels. Therefore, a breathalyzer has been introduced to determine whether an aerobic volume above the reference level has been introduced and to prevent false measurement of the subject by warning through warning means.

A breathalyzer using a heat sensor is disclosed among conventional breathalyzers for measuring exhalation as described above. The conventional breathalyzer using a heat sensor has a heat sensor installed in the exhalation passage, and when the temperature around the heat sensor decreases due to the exhalation of the subject, the length of the section where the temperature falls in the heat sensor and the width of the temperature change are measured. It was configured by detecting and calculating the aerobic quantity of the subject. In the case of the breathalyzer using the heat sensor, in order to detect a change in temperature, the temperature around the heat sensor must be maintained at a relatively high temperature, and thus a heater part is required.

However, the method of measuring the air volume by detecting the temperature change as described above has a problem in that the measured value of the air volume is changed due to the external environment such as the ambient temperature. For example, assuming that the subject injects the same amount of exhalation, when the outside temperature is high, the change in temperature is large and a relatively high exhalation amount is measured, whereas when the outside temperature is low, the change in temperature is small and relatively Low expiratory volume may be measured. As described above, the method of measuring the amount of aerobic air by detecting a temperature change causes problems such as a lack of reliability of the measured data and a drunk driver to be punished. In addition, there is a problem that the structure is complicated and the manufacturing cost rises by installing a heater unit around the heat sensor.

The present invention has been proposed to solve the problems described above, it is possible to measure the air volume of the subject by minimizing the influence of the external environment, and to prevent the illegal measurement behavior of the subject through more accurate air volume measurement and warning And, its purpose is to provide a breathalyzer that can be manufactured at a relatively low cost.

The breathalyzer of the present invention for achieving the above object, the housing 10 including an alcohol sensor 5 therein, and detachably mounted on one side of the housing 10, the subject to blow the breath In the breathalyzer having a buoy 15 to put, and the display means 20 is installed on the front of the housing 10 to display the blood alcohol concentration of the subject, the breath passage (25) connected to the inflamed 15 A microphone (35) installed in the circuit and configured to detect sound waves generated by exhalation and convert them into electrical signals; An amplifier (40) for amplifying and outputting an electrical signal output from the microphone (35); And receives the electrical signal output from the amplifier 40 And a microprocessor 50 that compares with a predetermined reference value and outputs a warning signal when the reference value is not met.

According to a preferred embodiment, the microprocessor 50 extracts the magnitude or frequency of the sound waves generated by the exhalation from the electrical signal output from the microphone 35, calculates the exhalation amount from the extracted information, and It determines whether it lasts for a time and outputs a warning signal.

According to the breathalyzer of the present invention, by using a microphone to detect the sound wave signals generated by the subject's exhalation, the microprocessor calculates the air volume using the magnitude or frequency of the sound, thereby minimizing the influence of the external environment In this state, the aerobic volume of the subject can be measured, thereby making it possible to more accurately measure the aerobic volume, thereby improving the efficiency of the crackdown service and making it easier to detect fraudulent measurement. In addition, according to the present invention, by installing a microphone in the exhalation passage to measure the aspirator amount of the subject, compared to the conventional aerobic measurement configuration, the structure is very simplified and there is an effect that can significantly reduce the manufacturing cost.

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

1 is an external perspective view illustrating a breathalyzer according to an embodiment of the present invention, and FIG. 2 is a block diagram of the breathalyzer of FIG. 1.

Referring to Figure 1, the breathalyzer of the present invention is mounted on one side of the housing 10, the detachable 15 is detachably mounted. As shown in FIG. 2, an inside of the housing 10 is provided with an exhalation passage 25 connected to the fire zone 15, and an outlet 30 is formed at an end of the exhalation passage 25. An alcohol sensor 5 for detecting the amount of alcohol is provided inside the exhalation passage 25. The microprocessor 50 installed inside the housing 10 calculates the blood alcohol concentration from the signal input from the alcohol sensor 5, and the calculated blood alcohol concentration is calculated through the display means 20 on the front of the housing 10. Is displayed. The general configuration of such a breathalyzer is the same as in the prior art, it will be omitted in the art will be omitted the detailed description.

At this time, the breathalyzer of the present invention, as shown in Figure 2, the microphone 35 is further installed in the exhalation passage (25). The microphone 35 is a means for converting a sound wave signal into an electrical signal as is commonly known. In the present invention, the microphone 35 is used to detect a sound generated by the exhalation of the subject through the exhalation passage 25 to the discharge port 30, that is, a sound wave signal. Although the position of the microphone 35 is conceptually illustrated in FIG. 2, the microphone 35 is preferably installed at an adjacent position of the outlet 30.

As shown, the amplifier 40 is installed at the rear end of the microphone 35. The amplifier 40 amplifies the electrical signal output from the microphone 35. The signal amplified by the amplifier 40 is input to the microprocessor 50. At this time, as shown, the A / D converter 45 is installed at the rear end of the amplifier 40, converts the analog signal output from the amplifier 40 to a digital signal and delivers it to the microprocessor 50. Meanwhile, in the illustrated example, the A / D converter 45 is separately installed at the input terminal of the microprocessor 50, but the A / D converter 45 may be embedded in the microprocessor 50 by itself. .

The microprocessor 50 extracts the magnitude or frequency of sound waves generated by the exhalation from the electrical signal output from the microphone 35 and calculates the exhalation amount using the same. The magnitude of the sound wave is determined by the flow rate of the exhalation and the resonance phenomenon in the exhalation passage 25, and the frequency is determined by the flow rate and the structure of the exhalation passage 25. For example, as the intensity of the exhalation injected by the subject increases, the frequency of the sound wave increases. The magnitude of the sound wave is generated at the maximum amplitude at a particular frequency. Therefore, in a state where the structure of the exhalation passage 25 is standardized, a correlation between the magnitude or frequency of the sound waves and the exhalation amount can be obtained as data through many experiments. These data are programmed into the microprocessor 50 and referred to for calculating the expiratory volume from the output of the microphone 35. Preferably, the magnitude and frequency of the sound waves are used together when calculating the aerobic amount in the microprocessor 50.

The microprocessor 50 compares the calculated aerobic amount with a preset reference value. If the calculated expiration volume does not meet the reference value, a warning signal is output. More preferably, the microprocessor 50 determines whether the amount of exhalation above the reference value lasts for a predetermined time (for example, 3 seconds or more). If a period in which the exhalation volume does not meet the reference value occurs within a given time, a warning signal is output. This is because in order to analyze the amount of alcohol in the alcohol sensor (5) it is necessary to detect the exhalation through the micro-vessels in the lung, because when the exhalation is cut off, the breathed oxygen is immediately detected, it is difficult to accurately measure the amount of alcohol.

The warning signal output from the microprocessor 50 may be displayed in various ways. For example, when a warning signal is output from the microprocessor 50, the display means 20 composed of seven segments or the like may display a warning phrase such as "Err" or "FAIL" in response to the warning signal. If an LCD is used as the display means 20, a warning sentence such as "re-measurement request" may be displayed.

However, it is more preferable to have a separate warning means (65) for displaying the warning signal output from the microprocessor (50). For example, as shown in Figure 1, the front of the housing 10 is equipped with a warning light, such as LED, and when a warning signal is output from the microprocessor 50, the warning light is turned on to perform a negative measurement behavior to the intermediary You can inform. At this time, the warning light is preferably composed of a red LED. On the other hand, although not shown, if the aerobic amount calculated in the microprocessor 50 or more, it may be displayed by turning on the green LED. As another example, the warning means 65 may be an acoustic warning means such as a buzzer.

As described above, the breathalyzer of the present invention detects sound waves generated by the exhalation of the microphone 35 installed in the exhalation passage 25, and the microprocessor 50 determines the sound waves from the sound wave signals detected by the microphone 35. Calculate aerobic volume by extracting magnitude or frequency. The microprocessor 50 compares the calculated aerobic amount with the aerobic amount set as a reference value, and outputs a warning signal when the microprocessor 50 does not meet the reference value. More specifically, the microprocessor 50 determines whether the amount of exhalation above the reference value lasts for a given time. As described above, in the method of calculating the air volume by detecting sound waves generated by the exhalation of the subject, the external environment such as the external temperature does not significantly affect the air volume measurement. Thus, the detection of the aerobic volume corresponding to the sound wave signal can be made more accurately. This makes it possible to measure the exhalation amount more accurately. Therefore, it is possible for the drunkard to perform the crackdown work without intervening subjective judgment, thereby improving the efficiency of the crackdown work, and more accurately detecting the cheating behavior of the subjects.

The present invention has another technical advantage. According to the present invention, a simple manufacturing process of installing the microphone 35 in the exhalation passage can produce a breathalyzer with an aerobic flow measurement function. Therefore, the present invention has the advantage of greatly simplifying the structure and significantly reducing the manufacturing cost compared to the conventional breathalyzer breathalyzer measuring function.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes are possible in the technical field of the present invention without departing from the technical spirit of the present invention. It will be clear to those of ordinary knowledge.

1 is a perspective view showing a breathalyzer according to an embodiment of the present invention

2 is a block diagram of the breathalyzer of FIG.

<Explanation of symbols for the main parts of the drawings>

5 alcohol sensor 10 housing

15: Buddha 20: indicating means

25: exhalation passage 30: outlet

35 microphone 40 amplifier

45: A / D converter 50: microprocessor

65: warning means

Claims (2)

A housing 10 including an alcohol sensor 5 therein, a detachable 15 mounted on one side of the housing 10, and an inflated body 15 through which a subject is to exhale, and a front surface of the housing 10. In the breathalyzer, which is installed and includes a display means 20 for displaying the blood alcohol concentration of the subject, A microphone (35) installed in the breath passage (25) connected to the bull statue (15) and detecting and converting sound waves generated by the breath into an electrical signal; An amplifier (40) for amplifying and outputting an electrical signal output from the microphone (35); And Receives an electrical signal output from the amplifier 40 And a microprocessor (50) which compares with a predetermined reference value and outputs a warning signal when the reference value is lower than the predetermined reference value. The method of claim 1, The microprocessor 50 extracts the magnitude or frequency of the sound waves generated by the exhalation from the electrical signal output from the microphone 35, calculates the exhalation amount from the extracted information, and determines whether the exhalation amount above the reference value lasts for a given time. The breathalyzer, characterized in that for outputting a warning signal.

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