JP2010223902A - Alcohol detector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an alcohol detector for improving the reliability. <P>SOLUTION: The alcohol detector 1 includes an alcohol sensor 4 for detecting the alcohol concentration of a gas; a CO2 sensor 6 for detecting a CO2 generated due to heat applied by the alcohol sensor 4; and an ECU 2 for detecting deterioration in the alcohol sensor 4, based on a detection result of the CO2 by the CO2 sensor 6. The alcohol detector 1 estimates the quantity of a sticking substance, such as, dust which is a cause of the deterioration in the alcohol sensor 4, based on the detection result of the CO2 generated due to heat applied by the alcohol sensor 4, and can detect the deterioration in the alcohol sensor 4. Since the alcohol detector 1 can avoid false detection of the alcohol concentration by the deteriorated alcohol sensor 4, reliability of the apparatus can be improved. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an alcohol detection device.

  Conventionally, as a technique in such a field, for example, a spirit checker described in JP-A-2006-201097 is known. In this alcoholic checker, a heater is incorporated in the vicinity of the alcohol sensor, and the alcohol sensor is heat-cleaned by the heater, thereby preventing the alcohol sensor from being deteriorated due to dirt or the like.

JP 2006-201097 A

  By the way, in the above-described alcoholic beverage checker, the alcohol sensor is prevented from being deteriorated by heat cleaning, but the deterioration of the alcohol sensor is not detected. For this reason, it is impossible to determine whether the alcohol sensor is in a deteriorated state, for example, whether it is normalized by heat cleaning, and there is a problem that the reliability of the alcohol sensor, that is, the reliability of the apparatus is low.

  The present invention has been made to solve such problems, and improves the reliability by detecting the deterioration of the alcohol sensor based on the detection result of the specific gas component generated by heating the alcohol sensor. An object of the present invention is to provide an alcohol detection device capable of achieving the above.

  The present invention is an alcohol detection device including an alcohol sensor that detects the alcohol concentration of a gas, and includes a specific gas component detection unit that detects a specific gas component generated by heating the alcohol sensor, and a specific gas component detection unit. Deterioration detecting means for detecting deterioration of the alcohol sensor based on the detection result of the specific gas component.

  According to the alcohol detection device of the present invention, based on the detection result of a specific gas component such as CO 2 generated by heating the alcohol sensor, for example, the amount of adhering matter such as dust that is a cause of deterioration of the alcohol sensor is estimated. It becomes possible to detect the deterioration of the alcohol sensor. Therefore, according to this alcohol detection device, it is possible to avoid erroneous detection of the alcohol concentration by the deteriorated alcohol sensor, so that the reliability of the device can be improved.

  Further, the air flow generation means for generating an air flow directed from the outside to the specific gas component detection means via the alcohol sensor is provided, and the deterioration detection means detects the specific gas component from the periphery of the alcohol sensor by the air flow from the time of the generation of the air flow. Preferably, the detection result of the specific gas component flowing from the outside to the specific gas component detection means is determined based on the detection time difference until the specific gas component flowing to the means is detected.

  For example, in an alcohol detection device that detects the alcohol concentration of exhaled breath of a subject, the specific gas component detected by the specific gas component detection means is generated by heating of the alcohol sensor, or is exhaled from outside. It is necessary to determine whether it is included. Therefore, an air flow from the outside to the specific gas component detection means is generated via the alcohol sensor, and from the time of this air flow generation until the detection of the specific gas component flowing from the periphery of the alcohol sensor to the specific gas component detection means by this air flow. Recognize the difference in detection time. Since the specific gas component around the internal alcohol sensor is detected before the specific gas component of exhaled breath drawn from outside, the detection result of the specific gas component generated by heating the alcohol sensor is calculated based on the detection time difference. It becomes possible to recognize.

  The specific gas component is preferably carbon dioxide. It is possible to improve the reliability of the device for detecting the deterioration of the alcohol sensor by adopting carbon dioxide, which generates an amount corresponding to the amount of dust and other deposits combusted by heating the alcohol sensor, as the specific gas component It becomes.

  According to the present invention, it is possible to improve the reliability of the alcohol detection device.

It is a block diagram which shows the structure of one Embodiment of the alcohol detection apparatus which concerns on this invention. It is a front view which shows an alcohol detection apparatus. It is a figure which shows the usage example of an alcohol detection apparatus. It is the schematic which shows arrangement | positioning of the fan shown in FIG. 1, and various sensors. It is a graph which shows the time change of the CO2 amount which the CO2 sensor of FIG. 1 detected. It is a flowchart which shows the process of ECU of FIG.

  DESCRIPTION OF EMBODIMENTS Hereinafter, a preferred embodiment of an alcohol detection device according to the present invention will be described in detail with reference to the drawings.

  As shown in FIGS. 1 to 3, the alcohol detection device 1 according to this embodiment is a box-shaped device provided near the driver's seat of the vehicle, and is electrically connected to the vehicle through wiring. In front of the alcohol detection device 1, an insufflation port T through which the subject S inhales exhalation is provided, and the alcohol concentration of the exhalation inhaled into the insufflation port T is detected. The alcohol detection device 1 has an ECU [Electric Control Unit] (deterioration detection means) 2 for comprehensively controlling the device.

  The ECU 2 includes a CPU [Central Processing Unit] that performs arithmetic processing, a ROM [Read Only Memory] and a RAM [Random Access Memory] serving as a storage unit, an input signal circuit, an output signal circuit, a power supply circuit, and the like. The ECU 2 is electrically connected to the switch 3, the alcohol sensor 4, and the interference gas sensor 5. Further, the ECU 2 is electrically connected to a CO 2 sensor (specific gas component detection means) 6, a fan (air flow generation means) 7, and an indicator 8. The switch 3 is a start switch for starting the alcohol detection device 1. By switching the switch 3 to the ON state, the alcohol detection device 1 is activated. Moreover, the alcohol detection apparatus 1 stops by switching the switch 3 to the OFF state.

  As shown in FIG.1 and FIG.4, the alcohol sensor 4 is arrange | positioned before the blowing inlet T in the alcohol detection apparatus 1, and detects the alcohol concentration in the air. The alcohol sensor 7 outputs alcohol concentration information related to the detected alcohol concentration to the ECU 2. In addition, the alcohol sensor 4 is provided with a heater for combusting deposits such as dust attached to the alcohol sensor 4, and heat cleaning is performed for a predetermined time (for example, 5 seconds) when the alcohol detection device 1 is started. Done.

  The interfering gas sensor 5 is disposed in the back side of the alcohol sensor 4 (opposite to the inlet T) in the alcohol detection device 1, and gas that interferes with alcohol concentration detection in the alcohol sensor 4 (that is, alcohol in the alcohol sensor 4 and alcohol). It detects the concentration of misperceived breath odor components, etc.). The interfering gas sensor 5 outputs interfering gas concentration information related to the detected interfering gas concentration to the ECU 2. Further, the interfering gas sensor 5 is provided with a heater for burning dust and other adhering matter adhering to the interfering gas sensor 5, and heat cleaning is performed for a predetermined time (for example, 5 seconds) when the alcohol detection device 1 is started. Done.

  The CO2 sensor 6 is disposed in the alcohol detection device 1 on the back side (opposite to the inlet T) of the interfering gas sensor 5, and detects carbon dioxide (CO2) in the air. The CO2 sensor 6 outputs CO2 information related to the detected CO2 to the ECU 2.

  The fan 7 is provided in the blowing port T in the alcohol detection apparatus 1, and produces an airflow by rotation. The fan 7 starts rotating upon activation of the alcohol detection device 1. The rotation of the fan 7 generates an air flow that sucks outside air into the air inlet T. This airflow flows through the alcohol detection device 1 in the order of the alcohol sensor 4, the interfering gas sensor 5, and the CO2 sensor 6, and then exits to the outside.

  The indicator 8 displays various information related to the alcohol detection device 1 to the subject S by lighting the lamp or the like. The indicator 8 displays, for example, that the sensor is in a failure state according to a command from the ECU 2.

  The ECU 2 acquires alcohol concentration information from the output from the alcohol sensor 4 and acquires interference gas information from the output from the interference gas sensor 5. Further, the ECU 2 acquires CO2 information from the output from the CO2 sensor 6.

  Based on the acquired CO2 information, the ECU 2 determines whether the amount of CO2 detected by the CO2 sensor 6 is equal to or greater than a predetermined exhalation breathing threshold. When the ECU 2 determines that the amount of CO2 is equal to or greater than the exhalation inhalation threshold, the ECU 2 determines that the exhalation of the subject has been infused into the apparatus. When the ECU 2 determines that the breath of the subject has been blown into the apparatus, the ECU 2 detects the alcohol concentration of the breath based on the alcohol concentration information and the disturbing gas information. Specifically, the ECU 2 recognizes the concentration of the interference gas in the alcohol detection device 1 based on the interference gas concentration information output from the interference gas sensor 5. Since the value of the alcohol concentration detected by the alcohol sensor 4 varies depending on the concentration of the interfering gas, the alcohol concentration in the alcohol concentration information is corrected according to the recognized concentration of the interfering gas, so that the alcohol concentration of the exhaled breath can be detected accurately. Do.

  On the other hand, if the ECU 2 determines that the amount of CO2 is not greater than or equal to the exhalation threshold, the ECU 2 determines whether or not the detected amount of CO2 is greater than or equal to a predetermined dust combustion threshold based on the CO2 information. When it is determined that the amount of CO2 is equal to or greater than the dust combustion threshold, the ECU 2 determines that heat cleaning has been performed in the alcohol sensor 4 or the disturbing gas sensor 5.

  When the ECU 2 determines that the heat cleaning has been performed in the alcohol sensor 4 or the interference gas sensor 5, the ECU 2 is based on a detection time difference (elapsed time until detection) from the start of the rotation of the alcohol detection device 1, that is, the rotation start of the fan 7. Then, a sensor (a sensor that is a source of detected CO2) that is a target of deterioration detection is determined. Specifically, as shown in FIG. 5, the ECU 2 detects that the CO 2 generated by heating (interrupting dust, etc.) of the disturbing gas sensor 5 by the air flow generated by the fan 7 from the time T0 when the fan 7 starts to rotate is CO 2 sensor. Information relating to the time T1-T0 up to the time T1 detected after flowing to 6 is stored in advance. The ECU 2 determines, based on the information on the time T1-T0 and the detection time difference, that the CO2 generation source currently being detected is the interfering gas sensor 5, that is, the deterioration detection target sensor is the interfering gas sensor 5. Similarly, the ECU 2 performs a time T2- from the time T0 when the fan 7 starts to rotate until a time T2 when CO2 generated by heating the alcohol sensor 4 by the airflow generated by the fan 7 flows to the CO2 sensor 6 and is detected. Information relating to T0 is stored in advance, and based on the information relating to this time T2-T0 and the detection time difference, it is determined that the target sensor for detection of deterioration is the alcohol sensor 4.

  The ECU 2 estimates the dust accumulation amount in the determined target sensor based on the CO2 information. Specifically, the ECU 2 recognizes the detected time change of the CO2 amount based on the CO2 information, and calculates the total value of the CO2 amount from when the CO2 amount starts to change until it returns to the normal value. Then, the ECU 2 estimates the amount of dust accumulated by adhering to the target sensor, based on a map relating to the total value of CO2 and the amount of dust accumulated in advance.

  The ECU 2 determines whether or not the estimated dust accumulation amount is equal to or greater than a predetermined deterioration determination threshold value. When the ECU 2 determines that the dust accumulation amount is equal to or greater than the deterioration determination threshold, the ECU 2 outputs a failure display command for causing the indicator 8 to display that the target sensor is in a failure state.

  Next, processing of the ECU 2 will be described with reference to the drawings. First, the alcohol detection device 1 is activated by switching the switch 3 to the ON state. When the alcohol detection device 1 is activated, the fan 7 starts to rotate. At the same time, heat cleaning is performed in the alcohol sensor 4 and the interference gas sensor 5.

  As shown in FIG. 6, in step S <b> 1, various information (alcohol concentration information, interference gas information, CO2 information) is acquired by outputs from the alcohol sensor 4, the interference gas sensor 5, and the CO2 sensor 6.

  Next, based on the acquired CO2 information, it is determined whether or not the amount of CO2 detected by the CO2 sensor 6 is equal to or greater than a predetermined exhalation breathing threshold (S2). When it is determined that the amount of CO2 is equal to or greater than the exhalation breathing threshold, it is determined that the exhalation of the subject has been blown into the apparatus, and the alcohol concentration of the breath is detected based on the alcohol concentration information and the disturbing gas information (S3). . When the alcohol concentration of exhaled breath is detected, a predetermined process such as locking the vehicle engine in a stopped state is performed, and then the process returns to step S1.

On the other hand, if it is determined in step S2 that the amount of CO2 is not equal to or greater than the exhalation threshold, whether or not the amount of CO2 is equal to or greater than a predetermined dust combustion threshold is determined based on the CO2 information ( S4). If it is determined that the amount of CO2 is not equal to or greater than the dust combustion threshold, it is determined that the normal time when CO2 due to dust combustion or the like is not detected, and the process returns to step S1.
On the other hand, when it is determined that the amount of CO2 is equal to or greater than the dust combustion threshold, it is determined that the alcohol sensor 4 or the interference gas sensor 5 has performed heat cleaning, and deterioration detection is performed based on the detection time difference from the start of rotation of the fan 7. The sensor to be the target of is determined (S5).

  Thereafter, the dust accumulation amount in the determined target sensor is estimated based on the CO2 information (S6). Then, it is determined whether or not the estimated dust accumulation amount is greater than or equal to a predetermined deterioration determination threshold value (S7). If it is determined that the dust accumulation amount is not equal to or greater than the deterioration determination threshold, it is determined that the target sensor can be normalized only by heat cleaning, and the process returns to step S1.

  If it is determined in step S7 that the dust accumulation amount is greater than or equal to the deterioration determination threshold, a failure display command for causing the indicator 8 to display that the target sensor is in a failure state is output (S8).

  According to the alcohol detection device 1 described above, the amount of adhering matter such as dust that is a cause of deterioration of the alcohol sensor 4 is estimated based on the detection result of CO2 generated by heating the alcohol sensor 4. 4 can be detected. Therefore, according to the alcohol detection device 1, it is possible to avoid erroneous detection of the alcohol concentration by the deteriorated alcohol sensor 4, so that the reliability of the device can be improved.

  In addition, the alcohol detection device 1 sucks external air into the air inlet T by rotation, and also generates a fan 7 that passes through the alcohol sensor 4 and the interfering gas sensor 5 in this order and generates an air flow toward the CO 2 sensor 6. I have. Then, the ECU 2 starts from the time T1-T0 from the time T0 when the rotation of the fan 7 is stored in advance to the time T1 when the CO2 generated by the heating of the interfering gas sensor 5 flows to the CO2 sensor 6 and from the time T0 when the rotation of the fan 7 starts. Based on the information about the time T2-T0 until the time T2 when the CO2 generated by the heating of the alcohol sensor 4 flows to the CO2 sensor 6 and the difference in the detection time from the start of the rotation of the fan 7, it is generated by the heating of which sensor. It is possible to recognize whether the detection result is CO 2, and thereby it is possible to determine a sensor that is a target of deterioration detection.

  Moreover, in this alcohol detection apparatus 1, the carbon dioxide (CO2) which produces | generates the quantity according to the accumulation amount of the dust combusted by heat cleaning is employ | adopted as a specific gas component as described in a claim. It is possible to improve the reliability regarding the estimation of the amount of deposit, that is, the reliability of the alcohol detection device 1.

  The present invention is not limited to the embodiment described above. For example, it is determined whether or not exhaled air is blown in advance from only the amount of CO2, but it is determined that exhaled air is blown based also on a detection time difference from the start of rotation of the fan 7 to the time when CO2 is detected. An aspect may be sufficient. In this case, as shown in FIGS. 4 and 5, the time T3 during which the exhaled breath of the subject S sucked from the outside flows to the CO2 sensor 6 is later than T1 and T2, and therefore the detection result of CO2 contained in the exhalation It is possible to distinguish the detection result of CO2 generated by heating the sensor. As a result, it is possible to avoid erroneous detection that exhaled air has been blown in the case where almost the same amount of CO2 as that of exhalation is generated by heating the alcohol sensor 4 and the interfering gas sensor 5, thereby improving the reliability of the apparatus. Figured.

  In addition, the alcohol detection device 1 may be configured to further include a sensor such as a humidity sensor. In this case, each sensor is arranged so that the distance from the CO2 sensor 6 is different between the blowing port T and the CO2 sensor 6, so that the deterioration can be detected by heat cleaning. Further, the CO2 sensor 6 itself may be heat cleaned. Further, the interference gas sensor 5 is not necessarily provided.

  Further, the start timing of the rotation of the fan 7 and the start of heat cleaning of the alcohol sensor 4 and the interference gas sensor 5 are not limited to the time when the alcohol detection device 1 is started, and are appropriately set according to the specifications. In addition, the specific gas component described in the claims is not limited to carbon dioxide, and what is attached to the alcohol sensor 4 or the like and causes deterioration is not limited to dust.

  DESCRIPTION OF SYMBOLS 1 ... Alcohol detection apparatus, 2 ... ECU (deterioration detection means), 4 ... Alcohol sensor, 6 ... CO2 sensor (specific gas component detection means), 7 ... Fan (air flow generation means).

Claims (3)

An alcohol detection device comprising an alcohol sensor for detecting the alcohol concentration of a gas,
Specific gas component detection means for detecting a specific gas component generated by heating the alcohol sensor;
A deterioration detecting means for detecting deterioration of the alcohol sensor based on a detection result of the specific gas component by the specific gas component detecting means;
An alcohol detection device comprising: An airflow generation means for generating an airflow directed from the outside toward the specific gas component detection means via the alcohol sensor;
The deterioration detection unit is configured to detect the alcohol sensor based on a detection time difference from the generation of the airflow to the detection of the specific gas component flowing from the periphery of the alcohol sensor to the specific gas component detection unit by the airflow. The alcohol detection device according to claim 1, wherein a detection result of a specific gas component generated by heating the gas is recognized.   The alcohol detection device according to claim 1, wherein the specific gas component is carbon dioxide.

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