JPH0593703A - Capacitance type alcohol concentration measuring instrument - Google Patents

Abstract

PURPOSE:To accurately correct the alcohol concentration of a liquid in accordance with the temperature of the liquid so as to improve the detection accuracy of the title instrument by performing temperature correction with different correction characteristics based on an area discrimination map stored in a temperature correction circuit. CONSTITUTION:On the temperature correction map 33 of a temperature correction circuit 32, two correction characteristic curves 33A and 33B which indicate the relation between the alcohol concentration of fuel when the temperature T of the fuel is a reference temperature of, for example, about 20 deg.C and sensor outputs V are plotted. The curve 33A is the correction curve for an area E1 in which the alcohol concentration is equal to or lower than a prescribed value M (for example, about 38%) and the curve 33B is for another area E2 in which the alcohol concentration is higher than the value M. The circuit 32 selects the curve 33A or 33B by discriminating whether the alcohol concentration is in the area E1 or E2 and corrects the output V of an alcohol sensor 1 to a value which corresponds to the output of the sensor 1 at the reference temperature of 20 deg.C. After correction, the circuit 32 outputs the corrected value to a injection quantity control circuit 21 as a standard sensor output Va.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is used, for example, in an automobile engine which uses an alcohol-blended fuel in which alcohol such as methanol is mixed with gasoline, and is suitable for detecting the alcohol concentration in the fuel. The present invention relates to a capacitance type alcohol concentration measuring device.

[0002]

2. Description of the Related Art In recent years, due to demands for environmental protection, energy saving, etc., attention has been paid to an alcohol-mixed fuel obtained by mixing alcohol such as methanol with gasoline as a fuel for automobiles. However, when this alcohol-mixed fuel is used in an engine, the theoretical air-fuel ratio differs depending on the alcohol concentration in the fuel.Therefore, an alcohol concentration measuring device is installed in the fuel pipe to measure the alcohol concentration, and injection is performed according to the alcohol concentration. It controls the amount of fuel injected from the valve. As this type of alcohol concentration measuring device, a capacitance type and an optical type are known.

Therefore, as a capacitance type alcohol concentration measuring device according to the prior art shown in FIGS. 5 to 7, a capacitance type alcohol sensor using a coaxial cylindrical counter electrode is used as a fuel injection control device for an automobile engine. The case where it is used is shown as an example.

In the figure, reference numeral 1 denotes an alcohol sensor as a concentration detecting section. The alcohol sensor 1 has a capacitance type alcohol having a coaxial cylindrical counter electrode from an inflow pipe 3 and a center electrode 6 which will be described later. It is configured as a sensor. Further, in the alcohol sensor 1, an LC type oscillating circuit for applying a voltage of a predetermined oscillating frequency f to the center electrode 6, and f-V for converting a frequency signal output via the oscillating circuit into a voltage signal. A sensor circuit including a conversion circuit and the like is provided (none of them is shown).

Reference numeral 2 denotes a casing which constitutes the alcohol sensor 1 together with the center electrode 6 and the like. The casing 2 has an inlet 3A provided in the middle of the fuel pipe toward the fuel pump (not shown) side, such as methanol. The inflow pipe 3 into which the gasoline mixed with the alcohol flows and the inflow pipe 3 is provided at an angle of about 90 °, and the outlet 4A is connected to the fuel pipe toward the injection valve (not shown) side. It is formed in a substantially L-shape or a substantially T-shape from the attached outflow pipe 4. The inflow pipes 3 and the outflow pipes 4 are formed of iron pipes plated with nickel or the like. Here, the inflow pipe 3 is a cylindrical outer electrode that is coaxially opposed to the center electrode 6.

Reference numeral 5 denotes a plug body fixed in the inflow pipe 3 and made of an insulating material, and 6 denotes a rod-shaped central electrode extending in the central axis direction of the inflow pipe 3 through the plug body 5. The center electrode 6 and the inflow pipe 3 form a coaxial cylindrical counter electrode. Then, the center electrode 6 and the inflow pipe 3 as the outer electrode are separated by 12 to 24 from the oscillation circuit of the sensor circuit.
By applying a voltage having a frequency of MHz,
The alcohol concentration in the alcohol-mixed fuel flowing in the inflow pipe 3 is detected as a detection capacitance Cs as shown in the following mathematical formula 1.

Here, the detection capacitance Cs is

[0008]

[Equation 1] However, l: length dimension of the center electrode 6 ε: permittivity of alcohol mixed fuel Ra: radius of the center electrode 6 Rb: radius of the inflow pipe 3 d: deviation of the center electrode 6 from the center axis of the inflow pipe 3 ..

The detected capacitance Cs is oscillated by the oscillation circuit in the sensor circuit, and the oscillation frequency f shown in the following equation 2 is obtained.
The oscillation frequency f is converted into a sensor output V which is a voltage signal via an fV conversion circuit or the like, and is output to a temperature correction circuit 17 described later.

Here, the oscillation frequency f is

[0011]

[Equation 2] However, L is the inductance of the oscillator circuit, and C is the capacitance of the oscillator circuit.

Reference numeral 7 denotes a conductive cylindrical body which is fitted to one end side of the inflow pipe 3 and is formed in a cylindrical shape from a conductive material, and 8 is provided on the one end side of the inflow pipe 3 via the conductive cylindrical body 7. 3 and 4 respectively show lid bodies formed of an insulating material in a stepped cylindrical shape, and the lid bodies 8 cover one end side of the inflow pipe 3.

Reference numeral 9 denotes a center electrode terminal provided on one end side of the lid body 8 and connected to the center electrode 6. The center electrode terminal 9 is formed by a nut 10 screwed to one end side of the center electrode 6. It is fixed via a washer 11. Reference numeral 12 denotes an outer electrode terminal that is sandwiched between the conductive tubular body 7 and the lid body 8 and is connected to the inflow pipe 3 through the conductive tubular body 7. The outer electrode terminal 12 is for the center electrode. Together with the terminal 9, it is connected to an oscillation circuit via a lead wire (not shown). Reference numeral 13 denotes an O-ring provided between the plug body 5 and the lid body 8 and provided on the inner peripheral side of the tip of the conductive cylindrical body 7. The O-ring 13 is an alcohol-mixed fuel in the inflow pipe 3. One end side of the inflow pipe 3 is liquid-tightly sealed in order to prevent the gas from leaking to the outside.

Reference numeral 14 denotes a temperature sensor as a temperature detecting portion fixed to the outer peripheral side of the inflow pipe 3 with an adhesive 15.
The temperature sensor 14 is composed of a semiconductor type temperature sensitive element such as a thermistor or a posistor. The temperature sensor 14 detects the temperature (fuel temperature) of the alcohol-mixed fuel flowing in the inflow pipe 3 via the inflow pipe 3 and outputs it as the detected temperature T to the temperature correction circuit 17.

In FIG. 6, 16 is a control unit mounted on an automobile, and 17 is an injection amount control circuit 2 described later.
1 shows a temperature correction circuit as a temperature correction unit that constitutes the control unit 16 together with 1.
Is composed of a microcomputer or the like, and the alcohol sensor 1 and the temperature sensor 14 are connected to the input side thereof. Further, a temperature correction map 1 to be described later is stored in a storage area 17A including the ROM and the RAM of the temperature correction circuit 17.
8 is stored. Then, the temperature correction circuit 17
The temperature correction map 18 is read based on the detected temperature T from the temperature sensor 14, the sensor output V from the alcohol sensor 1 is corrected by the temperature correction map 18, and this voltage signal is output as the standard sensor output Va. ..

Reference numeral 18 is a storage area 17 of the temperature correction circuit 17.
A temperature correction map stored in A is shown. The temperature correction map 18 has a fuel temperature T of, for example, 2 as shown in FIG.
A correction characteristic line 18A showing the relationship between the alcohol concentration in the fuel and the sensor output V when the reference temperature is about 0 ° C. is stored as a map. Here, the sensor output V from the alcohol sensor 1 has temperature dependency, and when the temperature T is low at about 0 ° C., for example, the sensor output V is high as indicated by the output characteristic 19 shown by the chain double-dashed line in FIG. If the temperature T is as high as about 40 ° C., the output characteristic 20
As shown in, the sensor output V becomes low. Therefore, based on the temperature T from the temperature sensor 14, the temperature correction circuit 17 corresponds to the sensor output V at the reference temperature of 20 ° C. even when the temperature T is 0 ° C. or 40 ° C., for example. The value is corrected by the correction characteristic line 18A so that the standard sensor output Va is output to the injection amount control circuit 21.

Reference numeral 21 denotes an injection amount control circuit composed of a microcomputer or the like. The injection amount control circuit 21 is
A temperature correction circuit 17 on its input side, an air flow meter 22 for detecting the amount of intake air flowing into an intake manifold (not shown), and a crankshaft of the engine (not shown)
Is connected to a crank angle sensor 23 for detecting the engine speed, and an output side is connected with an injection valve 24 for injecting alcohol-mixed fuel into the combustion chamber of the engine, a fuel pump (not shown), and the like. ing. Then, the injection amount control circuit 21 calculates the fuel injection amount Ti by the injection amount calculation program stored in the storage area 21A.

[0018]

## _EQU3 ## Ti = Mk × Tp × α × α '× C _oef + Ts where Mk: constant determined from alcohol concentration Tp: basic injection amount α: air-fuel ratio feedback correction coefficient α': basic air-fuel ratio learning correction coefficient C _oef : Various correction coefficients Ts: Battery voltage correction coefficient, which is used to control the injection amount of fuel injected from the injection valve 24 into the combustion chamber.

The alcohol sensor according to the prior art has the above-mentioned structure, and when the alcohol mixed fuel discharged from the fuel pump flows into the inflow pipe 3 from the inflow port 3A, it is between the center electrode 6 and the inflow pipe 3. In addition, the detected electrostatic capacitance Cs shown in the above-mentioned Formula 1 is generated according to the alcohol concentration in the fuel, and this detected electrostatic capacitance Cs is output to the oscillation circuit via the terminals 9, 12 and the like. Then, the oscillating circuit oscillates the oscillating frequency f shown in the equation 2 based on the detected electrostatic capacitance Cs, and the oscillating frequency f is converted into a voltage by the fV converting circuit, and the temperature correcting circuit as the sensor output V. It is output to 17. Next, the temperature correction circuit 17 reads the detected temperature T from the temperature sensor 14, corrects the temperature of the sensor output V based on the correction characteristic line 18A of the temperature correction map 18, and uses this as the standard sensor output Va at the reference temperature. Output to the injection amount control circuit 21.

Then, the injection amount control circuit 21 uses the standard sensor output Va output from the temperature correction circuit 17, the intake air amount from the air flow meter 22, the engine speed from the crank angle sensor 23, etc. The fuel injection amount Ti is calculated based on the equation 3, and an injection signal corresponding to the fuel injection amount Ti is output to the injection valve 24 to perform fuel injection control according to the alcohol concentration in the fuel.

[0021]

By the way, in the electrostatic capacity type alcohol concentration measuring device according to the above-mentioned prior art,
Since the plug 5 and the O-ring 13 made of an insulating material are provided between the center electrode 6 and the inflow pipe 3, these plugs 5
The alcohol sensor 1 has an inherent capacitance due to the relative permittivity of the above. Since the relative permittivity of the plug body 5 and the like and the relative permittivity of gasoline are relatively close to each other, as shown in FIG. 7, the alcohol concentration in the fuel falls below a predetermined alcohol concentration M of about 8%. Therefore, in one alcohol concentration region E1 where the proportion of gasoline in the fuel is large, the output characteristics 19 and 20 have low temperature dependence, and the sensor output V
Is high.

However, according to the above-mentioned conventional technique, the correction characteristic line 18A of the temperature correction map 18 is set to the sensor output V in the other alcohol concentration region E2 where the alcohol concentration in the fuel becomes equal to or higher than the predetermined alcohol concentration M. Since a single straight line having an inclination of the angle θ is used in accordance with the characteristics, the output characteristics 19 and 20 actually change as shown by the two-dot chain line in FIG. In the range of the area E1, the temperature correction circuit 18 corrects the temperature according to the correction characteristic line 18A as shown by the dotted line in FIG. Therefore, in the range of the one alcohol concentration region E1 in which the alcohol concentration is equal to or lower than the predetermined alcohol concentration M, the error of the temperature correction becomes large and the detection accuracy of the alcohol concentration is significantly lowered, and the alcohol concentration in the fuel is reduced. Accordingly, there is a problem that the fuel injection amount cannot be optimally controlled and reliability is low.

The present invention has been made in view of the above-mentioned problems of the prior art. Even when the alcohol concentration in the liquid becomes a predetermined alcohol concentration or less, the alcohol concentration can be accurately temperature-corrected according to the temperature of the liquid. It is an object of the present invention to provide a capacitance type alcohol concentration measuring device capable of improving the detection accuracy of alcohol concentration.

[0024]

In order to solve the above-mentioned problems, the features of the structure adopted by the present invention are that the alcohol concentration of the liquid detected by the concentration detecting section and the temperature of the liquid detected by the temperature detecting section. Area determination means for determining whether the alcohol concentration in the liquid is in one alcohol concentration area having a predetermined alcohol concentration as a boundary or in another alcohol concentration area is provided, and the temperature correction unit is configured to determine the area determination means. When the temperature is determined to be in one alcohol concentration region, a first temperature correction means for performing temperature correction with one correction characteristic, and another correction when the region determination means is determined to be in another alcohol concentration region It is composed of a second temperature correction means for performing temperature correction based on characteristics.

[0025]

The area determining means is based on the alcohol concentration in the liquid detected by the concentration detecting portion and the temperature of the liquid detected by the temperature detecting portion, and the alcohol concentration in the liquid is one alcohol having a predetermined alcohol concentration as a boundary. Whether it is in the concentration region or another alcohol concentration region is determined. When the temperature determining unit determines that the region determining unit is in one alcohol concentration region, the first temperature correcting unit temperature-corrects the alcohol concentration based on the temperature detected by the temperature detecting unit, and When the area determination unit determines that the alcohol concentration is in another area, the second temperature correction unit corrects the alcohol concentration based on the temperature detected by the temperature detection unit.

[0026]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT An embodiment of the present invention will be described below with reference to FIGS. In the embodiment, the same components as those of the prior art shown in FIGS. 5 to 7 are designated by the same reference numerals, and the description thereof will be omitted.

In the figure, 31 is a control unit according to the present embodiment, 32 is a temperature correction circuit as a temperature correction unit which constitutes the control unit 31 together with the injection amount control circuit 21, and the temperature correction circuit 32 is a conventional technique. Almost the same as the temperature correction circuit 17 described above, it is composed of a microcomputer and the like, the alcohol sensor 1 and the temperature sensor 14 are connected to the input side, but in the storage area 32A of the temperature correction circuit 32, A temperature correction map 33 and a region determination map 34, which will be described later, are stored. Then, the temperature correction circuit 32 uses the area determination map 3
The temperature correction map 33 is read out based on the determination result of 4 and the alcohol sensor 1 is read by the temperature correction map 33.
The sensor output V from is corrected, and this voltage signal is output to the injection amount control circuit 21 as the standard sensor output Va.

Reference numeral 33 shows a temperature correction map. As shown in FIG. 2, the temperature correction map 33 shows the alcohol concentration in the fuel and the sensor output V when the temperature T of the fuel is a reference temperature of about 20.degree. One correction characteristic line 33 showing the relationship of
A and the other correction characteristic line 33B are stored as a map. Here, one correction characteristic line 33A is a sensor output V0 when the alcohol concentration is zero, according to the characteristics of the sensor output V in the one alcohol concentration region E1 below a predetermined alcohol concentration M (for example, about 8%). Is the starting point, and the sensor output V1 when the alcohol concentration is M is the ending point, and is formed in a gentle straight line having a predetermined angle θ1. The other correction characteristic line 33B is based on the characteristics of the sensor output V in the other alcohol concentration region E2 when the alcohol concentration is equal to or higher than the predetermined alcohol concentration M, and the sensor output V1 at the alcohol concentration M is the starting point. , Sensor output V2 when alcohol concentration is 100%
Is formed into a steep straight line having a predetermined angle θ2 (θ1 <θ2).

Then, the temperature correction circuit 32 determines from the area determination map 34 that one of the alcohol concentration areas E1 and E2 is
It is determined which of the alcohol concentration regions is in, and one of the correction characteristic lines 33A and 33B is selected in accordance with the determination result, whereby the sensor output V from the alcohol sensor 1 is changed to the reference temperature. The temperature is corrected to a value corresponding to the sensor output at 20 ° C., and this voltage signal is output to the injection amount control circuit 21 as the standard sensor output Va.

Further, in FIG. 3, reference numeral 34 is an area determination in which a relationship between the temperature T detected by the temperature sensor 14 and the sensor output V from the alcohol sensor 1 is stored as a map in the storage area 32A of the temperature correction circuit 32. Show map,
The area determination map 34 shows a boundary line 34 in the lower right direction showing the relationship between the temperature T and the sensor output V when the alcohol concentration in the fuel is substantially equal to the predetermined alcohol concentration M.
A, a determination region 34B formed below the boundary line 34A, which indicates that the alcohol concentration in the fuel is within the range of one alcohol concentration region E1, and formed above the boundary line 34A, It is composed of another determination area 34C which indicates that the alcohol concentration in the fuel is in another alcohol concentration area E2.

The alcohol sensor according to the present embodiment has the above-mentioned structure, and its basic operation is not different from that of the prior art. Therefore, next, the temperature correction processing by the temperature correction circuit 32 will be described with reference to FIG.

First, in step 1, the sensor output V from the alcohol sensor 1 is read, in step 2, the detected temperature T from the temperature sensor 14 is read, and in step 3, the area determination map shown in FIG. Three
Read 4. Then, in step 4, it is detected which one of the determination regions 34B and 34C of the region determination map 34 the intersection of the sensor output V and the detected temperature T is in, so that the alcohol mixing is performed. It is determined whether the alcohol concentration in the fuel is in one alcohol concentration region E1 having a predetermined alcohol concentration M as a boundary or in another alcohol concentration region E2. Specifically, it is determined whether or not it is in one alcohol concentration region E1.
When it is determined to be "YES" in this step 4, the intersection of the sensor output V and the temperature T exists in the determination area 34B of the area determination map 34, and the alcohol concentration in the fuel is within the alcohol concentration area E1. If so, go to step 5.

Next, in step 5, the temperature correction map 3
3 is read, and one correction characteristic line 3 of the temperature correction map 33 is read.
3A, the sensor output V at the temperature T is corrected to the sensor output at the reference temperature, and in step 6, this voltage signal is set as the standard sensor output Va to the injection amount control circuit 21.
Output to.

On the other hand, when "NO" is determined in step 4, the intersection of the sensor output V and the temperature T exists in the determination region 34C of the region determination map 34, and the alcohol concentration in the fuel is the alcohol concentration region. If it is within E2, go to step 7. And in this step 7,
The temperature correction map 33 is read, the sensor output V at the temperature T is corrected to the sensor output at the reference temperature by the other correction characteristic line 33B of the temperature correction map 33, and the process proceeds to step 6. At step 6, this voltage signal is The standard sensor output Va is output to the injection amount control circuit 21.

Thus, according to the present embodiment, according to the area determination map 34, the alcohol concentration in the fuel is in one alcohol concentration area E1 or in another alcohol concentration area E.
2 can be reliably determined, and the correction characteristic lines 33A and 33B corresponding to the alcohol concentration regions E1 and E2 can be determined.
By selectively using the alcohol sensor 1
The sensor output V from V can be temperature-corrected to the standard sensor output Va at the reference temperature. As a result, even if the alcohol concentration in the fuel is in the one alcohol concentration region E1 in which the alcohol concentration is equal to or lower than the predetermined alcohol concentration M, the temperature is accurately corrected by the one correction characteristic line 33A, and the alcohol concentration in the alcohol concentration region E1 is corrected. The detection accuracy of can be greatly improved. Further, as a result, the alcohol concentration can be accurately detected over a wide alcohol concentration range, and the reliability can be improved.

In the above embodiment, the area determination map 34 shown in FIG. 3 and step 3 and step 4 of the program shown in FIG. 4 are specific examples of the area determination means which is a constituent of the present invention. In the program shown in FIG. 4, step 5 is a specific example of the first temperature correction means which is a constituent of the present invention, and step 7 is a specific example of the second temperature correction means which is a constituent of the present invention. is there.

In the above embodiment, the temperature correction circuit 32 is used.
However, instead of this, the temperature correction circuit 32 may be provided on the sensor circuit side of the alcohol sensor 1 to reduce the load on the control unit side.

Further, in the above embodiment, the temperature correction circuit 3
2 is each correction characteristic line 33A, 33 of the temperature correction map 33.
Although it has been described that the sensor output V is temperature-corrected by using B, the present invention is not limited to this, and the temperature correction circuit 3 is used, for example.
In the second storage area 32A, each alcohol concentration area E1
, E2 may be stored as an arithmetic expression for temperature correction, and the temperature may be corrected by this arithmetic expression.

Further, in the above embodiment, the outflow pipe 4 is described as being provided at an angle of about 90 ° with respect to the inflow pipe 3, but instead of this, for example, the inflow pipe 3 and the outflow pipe 4 are formed. The angle may be 90 ° or more, and the inflow pipe 3 and the outflow pipe 4 may be straight pipes.

Furthermore, in the above-mentioned embodiment, the alcohol sensor 1 using the coaxial cylindrical counter electrode as the concentration detecting portion has been described as an example, but the present invention is not limited to this, and a parallel plate electrode is used. It can also be applied to an alcohol sensor.

Further, in the above embodiment, the case where the capacitance type alcohol concentration measuring device is used for measuring the alcohol concentration in the fuel of the automobile engine has been described as an example.
The present invention is not limited to this, and can be widely applied to the measurement of the alcohol concentration of various alcohol mixed liquids such as industrial alcohol and food alcohol.

[0042]

As described above in detail, according to the present invention, the area determining means is based on the alcohol concentration in the liquid detected by the concentration detecting section and the temperature of the liquid detected by the temperature detecting section.
It is possible to determine whether the alcohol concentration in the liquid is in one alcohol concentration region bounded by a predetermined alcohol concentration or in another alcohol concentration region. Then, when the temperature determining unit determines that the region determining unit is in one alcohol concentration region, the first temperature correcting unit determines the alcohol concentration with the one correction characteristic based on the temperature detected by the temperature detecting unit. If the area determining means determines that the alcohol concentration is in another alcohol concentration area, the second temperature correcting means corrects the alcohol concentration with another correction characteristic based on the temperature detected by the temperature detecting portion. You can
As a result, the alcohol concentration from the concentration detection unit can be accurately temperature-corrected over a wide range, the accuracy of alcohol concentration detection can be improved, and the reliability can be improved.

[Brief description of drawings]

FIG. 1 is a block diagram showing a circuit configuration of a capacitance type alcohol concentration measuring apparatus according to an embodiment of the present invention.

2 is a characteristic diagram showing a temperature correction map stored in a temperature correction circuit in FIG.

FIG. 3 is an explanatory diagram showing an area determination map.

FIG. 4 is a flowchart showing a temperature correction process.

FIG. 5 is a vertical sectional view showing an alcohol sensor according to a conventional technique.

FIG. 6 is a block diagram showing a circuit configuration of a capacitance type alcohol concentration measuring device.

7 is a characteristic diagram showing a temperature correction map stored in a temperature correction circuit in FIG.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Alcohol sensor (concentration detection part) 6 Central electrode 14 Temperature sensor (temperature detection part) 32 Temperature correction circuit (temperature correction part) 33 Temperature correction map 33A One correction characteristic line (one correction characteristic) 33B Other correction characteristic line (Other correction characteristics) 34 Area determination map M Predetermined alcohol concentration E1 One alcohol concentration area E2 Other alcohol concentration area

Claims (1)

[Claims] 1. A concentration detector for detecting the alcohol concentration in a liquid mixed with alcohol from the capacitance of the liquid interposed between electrodes, a temperature detector for detecting the temperature of the liquid, and the concentration detector. In the capacitance type alcohol concentration measuring device comprising a temperature correction unit that corrects the alcohol concentration detected by the temperature detection unit according to the temperature of the liquid detected by the temperature detection unit, Based on the alcohol concentration and the temperature of the liquid detected by the temperature detection unit, it is determined whether the alcohol concentration in the liquid is in one alcohol concentration region bounded by a predetermined alcohol concentration or in another alcohol concentration region. A region determination means is provided, and when the temperature determination part determines that the region determination means is in one alcohol concentration region, the first temperature is corrected with one correction characteristic. Capacitance formula characterized by comprising a correction means and a second temperature correction means for performing temperature correction with another correction characteristic when the area determination means determines that it is in another alcohol concentration area. Alcohol concentration measuring device.