JP2011053050A - Alcohol concentration detector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an alcohol concentration detector for reducing a burden of the process for implementing an alcohol concentration calculating calibration for calculating an alcohol concentration even if an alcohol sensor is replaced. <P>SOLUTION: An EEPROM 213 for storing calibration data for deriving an alcohol concentration calculating expression of the alcohol sensor 211 is mounted on a board 21 on which the alcohol sensor 211 is mounted, so that the sensor ASSY2 is configured. Thus, even if the sensor ASSY2 is replaced, the EEPROM 213 is replaced along with the alcohol sensor 211. Therefore, the alcohol concentration calculating expression of the alcohol sensor 211 after the replacement is defined based on the calibration data stored in the EEPROM 213. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an alcohol concentration detection device that is used, for example, to prevent drunk driving and detects the alcohol concentration contained in the exhalation of a subject such as an automobile driver.

  Conventionally, in order to prevent drunk driving, there is known an alcohol concentration detection device that detects the alcohol concentration contained in the expiration of an automobile driver (see, for example, Patent Documents 1 and 2). This type of alcohol concentration detector is equipped with a semiconductor sensor that uses a semiconductor such as a metal oxide that reacts with alcohol contained in the breath of the subject and exhibits physical properties (sensor physical properties) corresponding to the alcohol concentration. Is done.

  When an alcohol such as ethanol reacts with the semiconductor sensor, the sensor resistance as a sensor physical property changes according to the alcohol concentration. Therefore, an alcohol concentration calculation formula showing the relationship between the alcohol concentration and sensor physical properties is obtained in advance, and the alcohol concentration contained in exhalation is calculated by substituting the detected sensor physical properties into the alcohol concentration calculation formula. can do.

  By using such an alcohol concentration detection device, when an alcohol concentration higher than a reference value is detected in the expiration of an automobile driver, drunk driving can be prevented by, for example, disabling driving of the automobile. Can do.

JP 2004-212217 A JP 2009-42024 A

  By the way, in the semiconductor sensor, impurities such as silicon adhere to the surface of the semiconductor depending on the use environment, the use time, and the like, and the amount of the adherence increases with time. And when an impurity adheres to the semiconductor surface, the sensitivity with respect to alcohol will worsen. That is, the semiconductor sensor deteriorates depending on the use environment, use time, and the like. If a deteriorated semiconductor sensor is used, even if it reacts with an alcohol having the same alcohol concentration, the sensor resistance is different from that before deterioration, so that an incorrect alcohol concentration is calculated. Therefore, it is necessary to replace the semiconductor sensor periodically.

  However, since the characteristics of the semiconductor sensor after replacement do not exactly match the characteristics of the semiconductor sensor before replacement, the alcohol concentration calculation formula of the semiconductor sensor before replacement cannot be used as it is. Therefore, a calibration process is required to obtain a new alcohol concentration calculation formula that reflects the characteristics of the semiconductor sensor after replacement.

  Therefore, conventionally, as a calibration process, a gas whose alcohol concentration is known in advance is blown onto an alcohol concentration detection device equipped with a semiconductor sensor after replacement, and the sensor resistance of the semiconductor sensor is measured. That is, the sensor resistance is measured for each alcohol concentration. Then, an alcohol concentration calculation formula is obtained based on each measurement point. As described above, there is a problem that it is troublesome to perform such a calibration process for each replacement.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide an alcohol concentration detection device capable of reducing the inconvenience of the calibration process and easily replacing the semiconductor sensor.

In order to solve the above problems, an alcohol concentration detection device of the present invention reacts with alcohol contained in the breath of a subject and exhibits a physical property (hereinafter referred to as “sensor physical property”) according to the alcohol concentration. When,
The alcohol concentration calculation formula for calculating the alcohol concentration from the sensor physical property of the mounted semiconductor sensor which is the semiconductor sensor is a basic calculation formula common to the alcohol concentration calculation formula of other semiconductor sensors of the same type, and the mounted semiconductor sensor A replaceable sensor ASSY including a first storage means in which calibration data that is a constant is stored.
Basic calculation formula storage means for storing the basic calculation formula;
Sensor physical property measuring means for measuring the sensor physical property;
Reading means for reading the calibration data from the first storage means;
The alcohol concentration calculation formula determined based on the calibration data read by the reading means and the basic calculation formula stored in the basic calculation formula storage means, and the sensor physical properties measured by the sensor physical property measurement means. And an alcohol concentration calculating means for calculating the alcohol concentration based on the alcohol concentration.

  According to this, since the sensor ASSY on which the semiconductor sensor is mounted can be exchanged, the semiconductor sensor can be exchanged by exchanging the sensor ASSY with another sensor ASSY. Here, the alcohol concentration calculation formula is considered to be a formula consisting of a basic calculation formula common to the alcohol concentration calculation formulas of other semiconductor sensors of the same type and a constant unique to each semiconductor sensor. Therefore, the sensor ASSY is equipped with a first storage means in which calibration data, which is a constant unique to the semiconductor sensor, is stored. Therefore, when the sensor ASSY is replaced, the semiconductor sensor is replaced and the first storage means storing the calibration data corresponding to the replaced semiconductor sensor is replaced. The basic calculation formula is stored in the basic calculation formula storage means. Therefore, even if the semiconductor sensor is replaced, the alcohol concentration of the replaced semiconductor sensor is calculated based on the calibration data stored in the first storage unit and the basic calculation formula stored in the basic calculation formula storage unit. Formulas can be defined. Therefore, the alcohol concentration calculation means includes the alcohol concentration calculation formula determined based on the calibration data read by the reading means and the basic calculation formula stored in the basic calculation formula storage means, and the sensor physical properties measured by the sensor physical property measurement means. Based on the above, the alcohol concentration is calculated. Therefore, even if the sensor ASSY is replaced, the semiconductor sensor can be easily replaced because the calibration process for obtaining the alcohol concentration calculation formula again is not necessary for the replaced semiconductor sensor.

Further, as the calibration data, the alcohol concentration calculation formula itself may be stored instead of the above constant. That is, the alcohol concentration detection device of the present invention reacts with alcohol contained in the breath of the subject, and exhibits a physical property corresponding to the alcohol concentration (hereinafter referred to as “sensor physical property”);
A replaceable sensor ASSY, including first storage means storing calibration data that is an alcohol concentration calculation formula for calculating the alcohol concentration from the sensor physical properties of the mounted semiconductor sensor that is the semiconductor sensor;
Sensor physical property measuring means for measuring the sensor physical property;
Reading means for reading the calibration data from the first storage means;
And an alcohol concentration calculating means for calculating the alcohol concentration based on the calibration data read by the reading means and the sensor physical properties measured by the sensor physical property measuring means.

  According to this, even when there is no common basic calculation formula in the alcohol concentration calculation formula for each semiconductor sensor, when the semiconductor sensor is replaced, the alcohol concentration calculation formula itself is also replaced. This eliminates the need for a calibration process for obtaining a new alcohol concentration calculation formula for the replaced semiconductor sensor, so that the semiconductor sensor can be easily replaced.

In addition, the alcohol concentration detection device of the present invention includes a replacement presence / absence determination unit that determines whether or not the sensor ASSY has been replaced,
Second storage means for storing the calibration data read by the reading means,
If the replacement presence / absence determination unit determines that the sensor ASSY has not been replaced, the reading unit does not read the calibration data, and the alcohol concentration calculation unit stores the calibration data in the second storage unit. The alcohol concentration may be calculated using the previous calibration data stored as it is.

Regarding the determination method performed by the replacement presence / absence determination means, the identification number of the sensor ASSY is also stored in the first storage means.
The replacement presence / absence determination means can determine whether or not the sensor ASSY has been replaced based on whether or not the identification number stored in the first storage means has changed between the previous time and the current time.

  This makes it possible to easily and reliably determine whether the sensor ASSY has been replaced.

1 is a perspective view of an alcohol concentration detection device 1. FIG. 1 is an exploded view of an alcohol concentration detection device 1. FIG. It is the figure which showed the detail of the alcohol sensor 211. FIG. It is a figure for demonstrating the calculation method of alcohol concentration. It is the figure which showed the process which CPU17 performs when detecting alcohol concentration.

(First embodiment)
Hereinafter, a first embodiment of an alcohol concentration detection apparatus of the present invention will be described with reference to the drawings. FIG. 1 is a perspective view of the alcohol concentration detection device 1 according to the present embodiment as viewed obliquely from the front, FIG. 2 is an exploded view of the alcohol concentration detection device 1, and FIG. 3 is a diagram showing details of the alcohol sensor 211 of FIG. . First, the configuration of the alcohol concentration detection apparatus 1 will be described with reference to FIGS. In addition, this alcohol concentration detection apparatus 1 is provided, for example in a motor vehicle, and is used in order to prevent drunk driving. That is, the alcohol concentration detection device 1 detects the alcohol concentration contained in the driver's breath, and if the alcohol concentration is greater than a predetermined reference value, an engine ECU (not shown) that controls the engine Disable the driving of the car.

  The alcohol concentration detection device 1 has a size that can be gripped by the driver. As shown in FIGS. 1 and 2, an intake port 111 that takes in the driver's breath into the inside is formed on the front surface of the housing 10. Has been. When the driver detects the alcohol concentration, the driver grasps the alcohol concentration detection device 1, brings the intake 111 close to the mouth, and blows the intake 111.

  As shown in FIG. 2, the housing 10 includes a front cover 101 and a back cover 102, and the back cover 102 is formed with a discharge port 18 that discharges the exhaled air taken from the intake port 111. Has been. That is, exhaled air taken in from the intake port 111 travels in the exhalation flow channel 5, contacts with various sensors such as a semiconductor sensor 211 described later in the exhalation flow channel 5, and is then discharged from the exhaust port 18. It will be.

  In addition, the alcohol concentration detection device 1 is provided with a display unit 12 that displays the detection result of the alcohol concentration and the like. As shown in FIG. 1, the display unit 12 is exposed to the front surface of the housing 10 so that the driver can visually recognize the display state of the display unit 12.

  In addition, the alcohol concentration detection device 1 is provided with a switch 13 for instructing the start of alcohol concentration detection. As shown in FIG. 1, the head of the switch 13 is exposed on the front surface of the housing 10, and the driver The switch 13 can be pressed. When the switch 13 is operated by the driver, the fan 14 (see FIG. 2) provided in the housing 10 is driven, and the exhaled air blown by the driver is taken in.

  In addition, various sensors 211, 221, 231, and 232 are provided in the housing 10 for calculating the alcohol concentration contained in the exhaled breath in response to the exhaled breath that the driver blows. As shown in FIG. 2, these sensors 211, 221, 231, 232 are fixed to the substrate 21.

  The alcohol sensor 211 is a semiconductor sensor that reacts with alcohol contained in the breath of the subject and shows sensor resistance according to the alcohol concentration. Here, as shown in FIG. 3, the alcohol sensor 211 has a surface coated with a metal oxide 161 such as tin oxide and sintered. The surface of the alcohol sensor 211 is also coated with a coil 18C made of platinum so as to overlap the metal oxide 161.

  The function of the alcohol sensor 211 will be described. In the atmosphere (which contains no or very little alcohol), oxygen atoms in the atmosphere are bonded to electrons in the metal oxide 161 (tin oxide), so that it is difficult for electricity to flow through the metal oxide 161. It has become. On the other hand, when the breath containing alcohol is in contact with the metal oxide 161, the alcohol in the breath reacts with oxygen atoms on the surface, and the oxygen atoms bonded to the electrons in the metal oxide 161 are stripped off. As a result, electrons in the metal oxide 161 are released and electricity flows. This change is detected by the detection circuit 19 and the change in the electrical resistance value (sensor physical property) of the metal oxide 161 is measured, whereby the alcohol concentration in the breath is measured. The detection circuit 19 corresponds to the “sensor physical property measuring means” of the present invention.

  In addition, the alcohol sensor 211 may change the sensitivity to alcohol due to water vapor contained in the atmosphere. Therefore, periodically, the power supply circuit 18S connected to the coil 18C causes a current to flow through the coil 18C, and the metal oxide 161 is heated to a predetermined temperature to remove the adhering water vapor (aging).

As described above, the alcohol sensor 211 exhibits sensor physical properties corresponding to the reacted alcohol concentration. Here, FIG. 4A is a diagram illustrating a correspondence 61 between the sensor resistance R and the alcohol concentration X. FIG. In the present embodiment, the correspondence 61 between the alcohol concentration X and the resistance value R is a proportional relationship for convenience of explanation. As shown in FIG. 4A, the resistance value R of the alcohol sensor 211 decreases as the alcohol concentration X contained in the exhalation increases. This is because as the alcohol concentration X increases, the amount of oxygen atoms bonded to the electrons in the metal oxide 161 of the alcohol sensor 211 increases. For example, as shown in FIG. 4A, (1) when the driver blows exhaled air with an alcohol concentration x1, the alcohol sensor 211 indicates a resistance value r1, and (2) the resistance value r1 is detected by the detection circuit 19 ( (See FIG. 3). Therefore, if the correspondence 61 is obtained in advance, as shown in FIG. 4B, (3) the alcohol concentration x1 can be calculated from the detected resistance value r1. That is, the alcohol concentration x1 can be calculated by substituting the sensor resistance r1 into the alcohol concentration calculation formula (the following formula 1) showing the correspondence 61.
(Formula 1) Alcohol concentration X = A1 × (sensor resistance R) + C1

  Note that the alcohol concentration calculation formula of Formula 1 is a linear function with the sensor resistance of the slope A1 and the intercept C1 as a variable corresponding to the correspondence 61 for convenience of explanation, but the sensor resistance R and the alcohol concentration X The correspondence relationship and the alcohol concentration calculation formula are not limited to FIG.

  In the alcohol sensor 211, impurities such as silicon adhere to the surface of the metal oxide 161 depending on the use environment, use time, and the like, and the amount of the adherence increases with time. And when an impurity adheres to the metal oxide 161 surface, the sensitivity with respect to alcohol will worsen. That is, the alcohol sensor 211 deteriorates depending on the usage environment, usage time, and the like. If the deteriorated alcohol sensor 211 is used, even if the alcohol sensor 211 reacts with alcohol having the same alcohol concentration, the sensor resistance is different from that before deterioration, so that an incorrect alcohol concentration is calculated. Therefore, the alcohol sensor 211 needs to be replaced periodically.

However, since the alcohol sensor 211 after replacement does not exactly match the characteristics of the alcohol sensor 211 before replacement, the alcohol concentration calculation formula of the alcohol sensor 211 before replacement cannot be used as it is. However, for any alcohol sensor 211, the alcohol concentration calculation formula is expressed by a linear function formula with sensor resistance as a variable as shown in FIG. 4 and formula 1, and the slope A1 and the intercept C1 are the alcohol sensor. It is thought that it differs for every 211. That is, the alcohol concentration calculation formula is considered to be a formula consisting of a basic calculation formula of the following formula 2 and constants A1 and C1 specific to each alcohol sensor 211.
(Formula 2) Alcohol concentration X = A × (sensor resistance R) + C

  As shown in FIG. 2, the alcohol concentration detection apparatus 1 of the present invention includes an EEPROM 213 in which constants A1 and C1 specific to the alcohol sensor 211 are stored as calibration data on a substrate 21 on which the alcohol sensor 211 is mounted. Is provided. Although details will be described later, the calibration data stored in the EEPROM 213 is used when calculating the alcohol concentration.

  Further, the EEPROM 213 also stores the identification number OOXXX of the currently installed alcohol sensor 211. The EEPROM 213 corresponds to the “first storage unit” of the present invention.

  In addition to the alcohol sensor 211, an oxygen sensor 221, a humidity sensor 231, and a temperature sensor 232 are mounted on the substrate 21. The oxygen sensor 221 is a sensor that detects an oxygen concentration in an atmosphere such as exhaled air or the air. For example, the oxygen sensor 221 detects, as an electric current, movement of oxygen ions whose amount of passage is limited by a gas diffusion hole formed in a porous substrate. Thus, the oxygen concentration is detected.

  The humidity sensor 231 is a sensor that detects the humidity of the atmosphere. For example, the humidity sensor 231 detects the humidity by detecting a change in resistance due to adhesion of water molecules. Moreover, the temperature sensor 232 is a sensor that detects the temperature, and detects the temperature by detecting a change in resistance due to the temperature, for example.

  The oxygen sensor 221, the humidity sensor 231, and the temperature sensor 232 determine whether or not the driver's breath is included in the taken-in gas, as described in, for example, the above-mentioned Patent Document 2 (Japanese Unexamined Patent Application Publication No. 2009-4024). Or when the exhaled breath blown by the driver is diluted in the atmosphere, it is used to calculate the dilution rate.

  The alcohol sensor 211, oxygen sensor 221, humidity sensor 231, temperature sensor 232, EEPROM 213, and substrate 21 constitute a sensor ASSY 2. As described above, the alcohol sensor 211 deteriorates with time, so it needs to be replaced periodically. Therefore, in the present invention, the alcohol sensor 211 can be replaced in units of sensor ASSY2. That is, when the sensor ASSY2 is replaced, the alcohol sensor 211 is replaced and the EEPROM 213 is also replaced. Then, calibration data corresponding to the alcohol sensor 211 after replacement is stored in the EEPROM 213 of the sensor ASSY2 after replacement.

  Returning to FIG. 2, a CPU 17 is provided inside the housing 10, and the CPU 17 is mounted on the substrate 16. The substrate 16 is also equipped with a memory 171 such as an EEPROM, and the CPU 17 executes various processes for calculating the alcohol concentration in accordance with a program stored in the memory 171. The memory 171 functions as the “basic calculation formula storage unit” of the present invention, and stores the basic calculation formula of the above formula 2. Further, the memory 171 stores calibration data (constants A1, C1) and identification numbers ΔΔΔΔ stored in the EEPROM 213 mounted on the sensor ASSY2 mounted at the time of the previous alcohol concentration calculation. ing. Therefore, the memory 171 corresponds to the “second storage unit” of the present invention.

  Next, processing executed by the CPU 17 when detecting the alcohol concentration will be described with reference to the flowchart of FIG. The process of the flowchart is started when the switch 13 (see FIG. 1) is operated by the driver, for example.

  First, in step S11, the identification number OOXXX of the sensor ASSY2 is read from the EEPROM 213 mounted on the sensor ASSY2. In the subsequent step S12, the read identification number XXX is compared with the identification number ΔΔΔΔ stored in the memory 171 to determine whether the sensor ASSY2 has been replaced with another sensor ASSY2. . The CPU 17 that executes step S12 corresponds to the “replacement presence / absence judging means” of the present invention. If the identification number XXX matches the identification number ΔΔΔΔ, it is determined that the sensor ASSY2 has not been replaced, and the process proceeds to step S15.

In step S15, the calibration data (constants A1 and C1) stored in the memory 171 are used as they are to calculate the alcohol concentration contained in the driver's breath. Specifically, the fan 14 is first driven to capture the driver's breath, and the sensor resistance of the alcohol sensor 211 detected by the detection circuit 19 (see FIG. 3) is acquired. Then, the alcohol concentration calculation formula (see the following formula 3) based on the basic calculation formula (see the above formula 2) stored in the memory 171 as well as the calibration data (constants A1, C1) stored in the memory 171. Determine. The alcohol concentration is calculated by substituting the sensor resistance into the alcohol concentration calculation formula. Thereafter, the process of the flowchart of FIG.
(Expression 3) Alcohol concentration X = A1 × (sensor resistance R) + C1

  In step S15, when the calculated alcohol concentration is larger than a predetermined reference value, this is displayed on the display unit 12, and this is notified to an engine ECU (not shown). The engine ECU disables driving of the automobile and prevents drunk driving.

  On the other hand, it is assumed that the sensor ASSY2 is replaced with another sensor ASSY2. Then, the calibration data stored in the EEPROM 213 of the sensor ASSY2 after replacement is assumed to be constants A2 and C2. In this case, in step S11, the identification number of the sensor ASSY2 after replacement is read from the EEPROM 213 mounted on the sensor ASSY2 after replacement. In the subsequent step S12, since the read identification number XXX does not match the identification number ΔΔΔΔ stored in the memory 171, it is determined that the sensor ASSY2 has been replaced with another sensor ASSY2, and the processing is performed. Advances to step S13.

  In step S13, calibration data (constants A2 and C2) stored in the EEPROM 213 of the sensor ASSY2 after replacement is read out. The CPU 17 executing step S13 corresponds to the “reading unit” of the present invention. In the subsequent step S14, the identification number OOXXX of the sensor ASSY2 after replacement and the read calibration data (constants A2, C2) are stored in the memory 171 instead of those of the sensor ASSY2 before replacement. . Thereby, from the next time, it is determined whether or not the sensor ASSY2 has been replaced based on the identification number of the sensor ASSY2 after the replacement and the calibration data (constants A2 and C2) (S12). The alcohol concentration can be calculated (S15).

  Thereafter, in step S15, an alcohol concentration calculation formula is determined based on the calibration data (constants A2, C2) of the sensor ASSY2 after replacement. In this case, in the above equation 3, constants A2 and C2 are replaced instead of the constants A1 and C1. And then. The alcohol concentration is calculated based on the determined alcohol concentration calculation formula. The CPU 17 executing step S15 corresponds to the “alcohol concentration calculating means” of the present invention. Thereafter, the process of the flowchart of FIG.

  As described above, in this embodiment, the EEPROM 21 on which the calibration data of the alcohol sensor 211 is stored is also mounted on the substrate 21 on which the alcohol sensor 211 is mounted to configure the sensor ASSY2. When the sensor ASSY2 is replaced, the EEPROM 213 is also replaced together with the alcohol sensor 211. Therefore, the alcohol concentration calculation formula of the alcohol sensor 211 after replacement can be determined based on the calibration data stored in the EEPROM 213 and the basic calculation formula stored in the memory 171. This eliminates the need for a calibration step for obtaining a new alcohol concentration calculation formula for the alcohol sensor 211 after replacement, so that the alcohol sensor 211 can be easily replaced.

(Second embodiment)
Next, the second embodiment of the alcohol concentration detection device of the present invention will be described focusing on the differences from the first embodiment. In the first embodiment, the calibration data is a constant specific to the alcohol sensor 211 of the alcohol concentration calculation formula. However, in this embodiment, the alcohol concentration calculation formula itself of each alcohol sensor 211 is stored in the EEPROM 213 as the calibration data. Remembered. Other configurations and processes are the same as those in the first embodiment.

  When calculating the alcohol concentration, the alcohol concentration calculation formula is read from the EEPROM 213, and the alcohol concentration is calculated based on the alcohol concentration calculation formula.

  Also in this case, when the sensor ASSY2 is replaced, the EEPROM 2 storing the alcohol concentration calculation formula of the alcohol sensor 211 after replacement is also replaced. Since the calibration step for obtaining the calculation formula becomes unnecessary, the alcohol sensor 211 can be easily replaced. In addition, it is possible to deal with a case where there is no basic calculation formula common to each alcohol concentration calculation formula.

  The alcohol concentration detection device of the present invention is not limited to the above-described embodiment, and can be variously modified without departing from the scope of the claims. For example, in the above embodiment, the sensor ASSY2 is configured by mounting the sensors 221, 231, 232 other than the alcohol sensor 211 on the substrate 21, but the sensors 221, 231, 232 may be provided on another substrate.

1 Alcohol concentration detection device 2 Sensor ASSY
17 CPU
19 Detection circuit (sensor physical property measuring means)
21 Substrate 171 Memory (basic calculation formula storage means, second storage means)
211 Alcohol sensor (semiconductor sensor)
213 EEPROM (first storage means)
S12 Replacement existence judging means S13 Reading means S15 Alcohol concentration calculating means

Claims (4)

A semiconductor sensor that reacts with alcohol contained in the breath of the subject and exhibits physical properties according to the alcohol concentration (hereinafter referred to as “sensor physical properties”);
The alcohol concentration calculation formula for calculating the alcohol concentration from the sensor physical property of the mounted semiconductor sensor which is the semiconductor sensor is a basic calculation formula common to the alcohol concentration calculation formula of other semiconductor sensors of the same type, and the mounted semiconductor sensor A replaceable sensor ASSY including a first storage means in which calibration data that is a constant is stored.
Basic calculation formula storage means for storing the basic calculation formula;
Sensor physical property measuring means for measuring the sensor physical property;
Reading means for reading the calibration data from the first storage means;
The alcohol concentration calculation formula determined based on the calibration data read by the reading means and the basic calculation formula stored in the basic calculation formula storage means, and the sensor physical properties measured by the sensor physical property measurement means. And an alcohol concentration calculating means for calculating the alcohol concentration based on the alcohol concentration detecting device. A semiconductor sensor that reacts with alcohol contained in the breath of the subject and exhibits physical properties according to the alcohol concentration (hereinafter referred to as “sensor physical properties”);
A replaceable sensor ASSY, including first storage means storing calibration data that is an alcohol concentration calculation formula for calculating the alcohol concentration from the sensor physical properties of the mounted semiconductor sensor that is the semiconductor sensor;
Sensor physical property measuring means for measuring the sensor physical property;
Reading means for reading the calibration data from the first storage means;
Alcohol concentration detection means, comprising: an alcohol concentration calculating means for calculating the alcohol concentration based on the calibration data read by the reading means and the sensor physical properties measured by the sensor physical property measuring means. apparatus. Replacement presence / absence determining means for determining whether or not the sensor ASSY has been replaced;
Second storage means for storing the calibration data read by the reading means,
When the replacement presence / absence determination unit determines that the sensor ASSY has not been replaced, the reading unit does not read the calibration data, and the alcohol concentration calculation unit stores the calibration data in the second storage unit. The alcohol concentration detection apparatus according to claim 1, wherein the alcohol concentration is calculated using the stored previous calibration data as it is. The first storage means also stores the identification number of the sensor ASSY,
The exchange presence / absence judging means judges whether or not the sensor ASSY has been exchanged according to whether or not the identification number stored in the first storage means has changed between the previous time and the current time. Item 4. The alcohol concentration detection device according to Item 3.

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