KR20120083630A - Breath alcohol analyzer - Google Patents

Abstract

PURPOSE: A drunkometer is provided to accurately measure blood alcohol concentration and to heat sample gas with low energy. CONSTITUTION: A drunkometer with a sensor comprises: a blowing pipe for outbreathing; a sample gas inlet hole for injecting a sample gas from the blowing pipe; a sample gas collection unit having a sample gas channel with a sample gas outlet hole; and a heater placed at inner space of the sample gas channel. The heater has an insulation substrate(21) placed at inner space of the sample gas channel; a radiator(22) formed on the insulation substrate; and a plurality of stem pins(24) for supporting the insulation substrate .

Description

Breathalyzer {Breath Alcohol Analyzer}

The present invention relates to a breathalyzer, and more particularly, to a breathalyzer that can accurately measure the blood alcohol concentration of the subject by preventing the condensation of water in the sample gas collecting unit.

Breathalyzer measures the concentration of alcohol that is expelled with exhalation by mixing with air of inhalation. Alcohol discharged with exhalation is proportional to the concentration of alcohol in the blood, so measuring the concentration of alcohol contained in the exhalation can calculate the blood alcohol concentration.

The breathalyzer includes a sample gas collecting unit, a sensing unit, a signal processing unit, and a display unit. The sample gas collection part includes a bleeding band for exhaling the subject and a passage through which the sample gas flowing through the bleeding band flows. The detection unit includes an alcohol sensor that detects an alcohol component in the sample gas collected through the sample gas collection unit and generates an electrical signal. The signal processor functions to calculate blood alcohol concentration by analyzing the electrical signal from the alcohol sensor. The result calculated by the signal processor is displayed on the display.

Alcohol sensors of the sensing unit include a fuel cell type and a semiconductor type. Fuel cell type has the disadvantage of short life and slow response time while high accuracy, while semiconductor type has the disadvantage of relatively low accuracy instead of long life and fast response time.

Sample gas collection part of the configuration of the breathalyzer is one of the most important parts to ensure the accuracy of the breathalyzer with the alcohol sensor in the configuration of the breathalyzer. No matter how excellent the sensitivity of the alcohol sensor is, accuracy can be a problem if the exhalation of the subject is not accurately captured.

In particular, in winter, since the temperature is very low compared to the temperature of the exhalation, moisture contained in the exhalation of the subject can be condensed in the sample gas collection unit. The alcohol component is easily soluble in water. When the alcohol component is dissolved in water, since the alcohol concentration of the sample gas is lowered, there is a problem that the alcohol concentration cannot be accurately measured.

In addition, in order to accurately measure the blood alcohol concentration in the user's body should not be diluted by mixing the user's exhalation with the outside air. Such sampling is impossible if the user cannot blow more than a certain period of time under a certain intensity. In other words, the sample gas collection unit should be able to confirm that the sample is being collected correctly by finding out that the subject is exhaling more than a certain intensity.

An object of the present invention is to provide a breathalyzer that solves the problem that alcohol is dissolved in water generated by condensation during winter breathing so that the concentration of alcohol is low.

According to the present invention, in the breathalyzer having a detection unit for detecting the alcohol component, the inhalation of the subject to breathe exhalation, the sample gas inlet through which the sample gas is introduced, the sample gas is introduced A sample gas collecting unit having a sample gas passage including a sample gas outlet flowing out to the side; And a heater having an insulator substrate disposed in the sample gas passage, a heating element formed on the insulator substrate, and a plurality of stem pins electrically connected to the heating element and supporting the substrate. A breathalyzer is provided. Since the heater is provided in the sample gas passage, moisture in the sample gas can be condensed at the sample gas collecting portion, thereby preventing the alcohol in the sample gas from being dissolved, thereby making accurate measurement possible. In addition, by providing a heater directly inside the sample gas passage, the sample gas can be heated with little energy.

In addition, the substrate has electrode holes penetrating the substrate and electrically connected to the heating element, and the stem pins are electrically connected to the electrode holes to supply power to the heating element. A meter is provided. Preferably, a plurality of perforations penetrating the substrate is formed around the heating element of the substrate to prevent heat generated from the heating element from being transferred to the surroundings.

In addition, there is provided a breathalyzer, characterized in that the heating element and the stem pins are electrically connected by bonding with a wire.

In addition, by measuring the change in the electrical conductivity of the heating element, there is provided a breathalyzer, characterized in that for measuring the inflow of sample gas. Since the heating element can measure not only the heating of the sample gas but also the inflow of the sample gas, there is no need to install a separate pressure sensor.

In addition, the sample gas passage, there is provided a breathalyzer, characterized in that a plurality of sample gas outlets are formed so that a portion of the sample gas introduced through the sample gas inlet is discharged to the outside. If too much sample gas is introduced, it is difficult to be sufficiently heated through a small capacity heating element. The cross-sectional area of the sample gas passage is preferably larger than the area of the sample gas inlet and the sample gas outlet.

In addition, the bulge is connected to the exhalation inlet in which the exhalation of the subject is introduced, the exhalation outlet for transferring a part of the exhaled inlet to the sample gas passage, and discharges a part of the exhaled inlet to the outside Breathalyzer is provided, characterized in that it comprises an exhalation outlet. This is because when too much sample gas is introduced as described above, it is difficult to sufficiently heat through the heating element. It is preferable that the cross-sectional area of the exhalation outlet is wider than the cross-sectional area of the exhalation outlet. This is because if the cross-sectional area of the exhalation outlet is narrower than the cross-sectional area of the exhalation outlet, it is difficult for sufficient sample gas to flow into the sample gas inlet.

The drunk breaker according to the present invention is provided with a heater in the sample gas passage. Therefore, moisture in the sample gas can be condensed in the sample gas collecting unit, thereby preventing dissolution of the alcohol in the sample gas. This enables accurate measurement of the alcohol concentration in the sample gas. In addition, by providing a heater directly inside the sample gas passage, the sample gas can be heated with little energy.

1 is a block diagram of a breathalyzer according to one embodiment of the present invention.
FIG. 2 is a perspective view of the sample gas passage shown in FIG. 1.
3 is a cross-sectional view taken along the AA direction of the sample gas passage shown in FIG. 2.
4 is a sectional view taken along the BB direction of the sample gas passage shown in FIG. 2.
5 is a perspective view of a sample gas passage of a breathalyzer according to another embodiment of the present invention.
6 is a cross-sectional view taken along the AA direction of the sample gas passage shown in FIG. 5.
FIG. 7 is a sectional view taken along the BB direction of the sample gas passage shown in FIG. 5.
8 is a cross-sectional view showing yet another embodiment of the heater.
9 is a perspective view of the injuries of the breathalyzer according to another embodiment of the present invention.

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

1 is a block diagram of a breathalyzer according to one embodiment of the present invention. Referring to FIG. 1, the breathalyzer 1 includes a sample gas collecting unit 10, a heater 20, and a sensing unit 30.

The sample gas collecting unit 10 collects an appropriate amount of sample gas from the exhalation discharged from the mouth or nose of the subject and delivers the sample gas to the sensing unit 30. The sample gas collecting unit 10 passes through the sample gas passage 12 and the sample gas passage 12 through which the sample gas introduced through the candle holder 11, the breathing apparatus 11, exhales and exhales. And a sample gas storage unit 13 in which one sample gas stays and is discharged.

The candlestick 11 is in the form of a straw and is coupled to an upstream side of the sample gas passage 12. The Buddha 11 is detachable and easy to clean after use.

FIG. 2 is a perspective view of the sample gas passage shown in FIG. 1, and FIG. 3 is a cross-sectional view along the A-A direction of the sample gas passage shown in FIG. Referring to FIGS. 2 and 3, the sample gas passage 12 is connected to the fire zone 11, the sample gas inlet 121 through which the sample gas is introduced, the sample gas outlet 122 connected to the sample gas storage 13, and A sample gas discharge port 123 is provided. The sample gas outlet 123 is formed at the sample gas inlet 121 and immediately discharges a part of the sample gas introduced to the outside to prevent the temperature of the sample gas passage 12 from being lowered by a large amount of sample gas. It plays a role. In addition, the diameters of the sample gas inlet 121 and the sample gas outlet 122 are smaller than the inner diameter of the sample gas passage 12. This is to prevent the sample gas passage 12 from lowering due to the excessive amount of sample gas flowing in at one time.

A heater 20 is installed in the sample gas passage 12 to heat the sample gas in the sample gas passage 12. The heater 20 functions to prevent condensation of moisture contained in the sample gas. 4 is a cross-sectional view taken along the B-B direction of the sample gas passage shown in FIG. 2. 3 and 4, the heater 20 is bonded to the insulator substrate 21, the heating element 22 formed on the insulator substrate 21, the electrode pad 23 of the heating element 22, and the wire 25. A plurality of stem pins 24.

The insulator substrate 21 is not particularly limited, but an alumina (Al ₂ O ₃ ) substrate is preferably used. The thickness is mainly 0.250 mm, but is not limited thereto.

The heating element 22 is generally formed using platinum (Pt). An example of the method of forming the heating element 22 on the insulator substrate 21 is as follows. Gold can be formed on the surface of the alumina substrate using a laser so that the heater can be cut in cell units. Next, the surface of the alumina substrate on which gold is formed is washed. Then, after the platinum paste is applied to the surface of the washed alumina substrate by screen printing, it is dried to form a pattern. The pattern is generally formed in a zigzag form to allow sufficient heat generation. Finally, heat treatment is carried out in a vacuum or reducing atmosphere to remove the binder in the platinum paste, and the platinum is sintered.

The stem pin 24 serves to support the insulator substrate 21 to float at a predetermined height inside the sample gas passage 12, and the electrode pads 23 of the heating element 22 formed on the insulator substrate 21 are provided. And by a conductive wire 25. In other words, the insulator substrate 21 floats inside the sample gas passage 12 by the wire 25 in contact with the stem pin 24. The stem pin 24 is electrically coupled to the heating element 22 to serve to apply a current to the heating element 22. In addition, the electrical conductivity of the heating element 22 can also be measured through the stem pin 24 coupled with the heating element 22. Since platinum is a kind of static thermistor whose resistance value increases in proportion to temperature, the temperature of the heating element 22 can be known by measuring the electrical conductivity of the heating element 22. Since the temperature of the heating element 22 changes according to the flow rate of the sample gas flowing into the sample gas passage 12, by measuring the electrical conductivity of the heating element 22, it is possible to confirm whether or not the sample gas is sufficiently introduced. For example, when it is confirmed that the cell conductivity of the heating element 22 is returned to the level before the sample gas is introduced before the alcohol concentration measurement is completed in the detector 30, the sample gas is not sufficiently supplied. Can be.

A sample gas storage unit 13 is disposed downstream of the sample gas passage 12. The sample gas storage unit 13 communicates with the detection unit 30 to supply the sample gas to the detection unit 30. Sample gas remaining after being supplied to the sensing unit 30 is discharged to the outside.

The sensing unit 30 includes an alcohol sensor 31 and a suction pump 32 installed downstream of the alcohol sensor 31. As described above, since the detection unit 30 is in communication with the sample gas storage unit 13, when the suction pump 32 operates, the sample gas of the sample gas storage unit 13 is supplied to the detection unit 30. The sample gas supplied to the sensing unit 30 changes the electrical characteristics of the alcohol sensor 31 of the sensing unit 30. The alcohol sensor 31 uses a semiconductor sensor or an electrochemical sensor.

In addition, although not shown, the breathalyzer 1 includes a signal processor and a display unit. The signal processor may calculate the blood alcohol concentration of the subject by processing the electrical signal transmitted from the detector 30. In addition, the electrical conductivity data of the heating element 22 may be processed to determine whether the sample gas is sufficiently supplied.

The display unit displays the alcohol concentration calculated by the signal processor. If the sample gas is not sufficiently supplied, the indicator may notify the measurer that the sample gas is not sufficiently supplied through a lighting or alarm.

Hereinafter, the operation of the breathalyzer 1 according to an embodiment of the present invention will be described. When the start button (not shown) is pressed on the surface of the breathalyzer 1, the alcohol sensor 31 of the detector 30 is stabilized. At the same time, a current is applied to the heating element 22 through the stem pin 24 and the heater 20 is heated. When the stabilization is completed, the display shows that the measurement preparation is completed. When the subject injects an exhalation through the bulge 11, the sample gas is introduced through the sample gas inlet 121 of the sample gas passage 12. The sample gas and the exhaled components are the same, but for convenience the exhaled after passing through the sample gas inlet 121 is called a sample gas. Saliva contained in the introduced sample gas is discharged to the outside along with some sample gas through the sample gas discharge port 123. The introduced sample gas is heated by the heater 20. Therefore, condensation of moisture in the sample gas can be prevented. If the sample gas inlet 121 is too wide, the amount of sample gas introduced is too large to be sufficiently heated by the heater 20. On the contrary, if the sample gas inlet 121 is too narrow, sufficient sample gas is provided in the sensing unit 30. It is difficult to feed. As the sample gas is heated, the temperature of the heating element 22 formed in the heater 20 is lowered by the introduced sample gas, and as a result, the resistance value of the heating element 22 is lowered. This change in resistance is transmitted to the signal processor. The sample gas is heated in the sample gas passage 12 and then moves to the sample gas storage unit 13 through the sample gas outlet 122. When it is confirmed that the sample gas is sufficiently introduced through the change in the resistance value, a portion of the sample gas moved to the sample gas storage unit 13 is moved by the pump 32 of the sensing unit 30 to the alcohol of the sensing unit 30. Moving around the sensor 31 changes the electrical characteristics of the alcohol sensor 31. The pump 32 of the sensing unit 30 operates momentarily only about 4 seconds after the subject starts to exhale to collect a sample of the correct volume. The electrical characteristic change of the alcohol sensor 31 is transmitted to the signal processing unit, and the signal processing unit calculates blood alcohol concentration of the subject through calculation and transfers it to the display unit. The display unit displays the delivered blood alcohol concentration value outside of the breathalyzer. If the signal processing unit determines that the sample gas is not sufficiently introduced through the change in the resistance value of the heating element 22, the signal is sent to the display unit, and the display unit lights up or alarms to inform the operator that re-measurement is required.

5 is a perspective view of a sample gas passage of a breathalyzer according to another embodiment of the present invention, Figure 6 is a cross-sectional view in the AA direction of the sample gas passage shown in Figure 5, Figure 7 is a view of the sample gas passage shown in Figure 5 BB direction cross section. The embodiment shown in FIG. 5 differs only from the embodiment shown in FIG. 1 and the position of the sample gas outlet 124 of the sample gas passage 12 and the heater 40, and only this will be described in detail.

In this embodiment, the sample gas discharge port 124 is formed around the upstream side of the sample gas passage 12. The sample gas outlet 124 immediately discharges a portion of the introduced sample gas to the outside to prevent the temperature of the sample gas passage 12 from being lowered by a large amount of sample gas.

The heater 40 includes an insulator substrate 41, a heat generator 42 formed on the insulator substrate 41, and a plurality of stem pins 44 electrically connected to the heat generator 42.

In the insulator substrate 41, an electrode hole 43 penetrating the insulator substrate 41 is formed. The electrode hole 43 is electrically connected to the heating element 42.

A pair of perforations 45 are formed around the heat generating element 42. Since the perforated part 45 is not connected to the start point and the end point, the center portion of the insulator substrate 41 on which the heating element 42 is formed is not separated from the insulator substrate 41. The perforation part 45 plays a role of minimizing the diffusion of heat by the heating element 42 from the center of the heat-reducing body substrate 41 to the periphery. Without the perforations 45, heat generated in the heating element 42 may be diffused along the heat-reducing body substrate 41 and then transferred to the stem pin 44, which is not efficient for heating only the sample gas.

In the present embodiment, the perforations 45 and the heating element 42 can be formed as follows. After forming the electrode hole 43 and the perforation part 45 in the insulator substrate 41, the conductors 43 and the conductors connecting the heating element 42 and the electrode hole 43 are coated by screen printing. The heating element 42 pattern is formed at a central portion surrounded by the perforation portion 45 and is connected to the electrode hole 43 through a conductive wire. Next, the binder component in the applied platinum paste is removed through heat treatment, and the platinum is sintered to complete the heating element 42.

The stem pin 44 serves to support the insulator substrate 41 so as to float to the inside of the sample gas passage 12 at a predetermined height. The stem pin 44 is inserted into the electrode hole 43 formed in the insulator substrate 41 to generate a heating element ( 42 is electrically connected.

This embodiment is easy to automate in that wire bonding is not necessary, and the work efficiency is very excellent. In addition, the contact between the wire and the electrode pad by the external impact, or the defect itself such as breaking the wire itself has the advantage that is less likely to occur. In addition, as illustrated in FIG. 8, it is easy to integrate a plurality of insulator substrates 41 in a form in which a plurality of insulator substrates 41 are sequentially coupled to the stem pin 44.

9 is a perspective view of the injuries of the breathalyzer according to another embodiment of the present invention.

The inhalation 51 of the breathalyzer according to the present embodiment is connected to the exhalation inlet 511 and the sample gas inlet 121 through which exhalation of the subject is introduced, and transfers a part of the exhaled inlet to the sample gas passage 12. Exhalation outlet 512 and the exhalation outlet 513 to immediately discharge a portion of the exhaled flow to the outside.

The exhalation outlet serves to prevent the temperature of the sample gas passage easily lowered by introducing only a part of the exhaled inlet into the sample gas passage. The cross-sectional area of the exhalation outlet is preferably smaller than the cross-sectional area of the exhalation outlet. This is because the amount of sample gas flowing into the sample gas passage through the exhalation outlet may be too small compared to the cross-sectional area of the exhalation outlet.

While one embodiment of the present invention has been described above, it is apparent that various modifications are possible without departing from the scope of the present invention. For example, although described as having a separate sample gas storage unit 13, the sample gas passage 12 and the detection unit 30 may be directly connected to supply the sample gas to the detection unit 30.

In addition, although the perforated part 45 is illustrated as being a pair of perforated parts 45 surrounding the heating element 42 in a c-shape, it may be curved, or may be a form in which several pairs overlap.

In addition, the heaters 20 and 40 have been described as using the heating elements 22 and 42 printed on the insulator substrates 21 and 41, but a heater such as platinum or a nichrome wire coil may be used.

1: breathalyzer
10: sample gas collecting unit 11: fire
12: Sample gas passage 13: Sample gas storage unit
20, 40: heater 21, 41: insulator substrate
22, 42: heating element 23: electrode pad
24, 44: stem pin 25: wire
30: detection unit 31: alcohol sensor
32: pump 45: perforation

Claims (11)

In the breathalyzer with a detector for detecting an alcohol component,
A sample gas passage including a fire inhalation exhaled by the subject, a sample gas inlet through which the sample gas is introduced, and a sample gas outlet through which the introduced sample gas flows out to the sensing unit; Collecting section; And
A heater disposed in an inner space of the sample gas passage;
Breathalyzer characterized in that it comprises a. The method of claim 1,
The heater,
And an insulator substrate disposed in the inner space of the sample gas passage, a heating element formed on the insulator substrate, and a plurality of stem pins electrically connected to the heating element and supporting the insulator substrate. . The method of claim 2,
The insulator substrate has electrode holes penetrating the insulator substrate and electrically connected to the heating element.
The stem pins are electrically connected to the electrode holes, characterized in that for supplying power to the heating element. The method of claim 3,
And a plurality of perforations penetrating the substrate are formed around the heating element of the substrate to prevent the heat generated from the heating element from being transferred to the surroundings. The method of claim 2,
Breathalyzer, characterized in that the heating element and the stem pins are electrically connected by bonding with a wire. The method of claim 2,
Measuring a change in the electrical conductivity of the heating element, the breathalyzer, characterized in that for measuring the inflow of sample gas. The method of claim 1,
The sample gas passage is a drinking meter, characterized in that a plurality of sample gas outlets are formed so that a portion of the sample gas introduced through the sample gas inlet is discharged to the outside. The method of claim 1,
And a cross-sectional area of the sample gas passage is wider than an area of the sample gas inlet and the sample gas outlet. The method of claim 2,
The heating element is a breathalyzer, characterized in that formed by screen printing. The method of claim 1,
The inflation,
Exhalation inlet for exhalation of the subject,
Connected to the sample gas inlet, exhalation outlet for transferring a portion of the exhaled flow into the sample gas passage, and
Breathalyzer characterized in that it comprises a exhalation outlet for discharging a part of the exhaled flow to the outside. The method of claim 10,
Breathalyzer is characterized in that the cross-sectional area of the exhalation outlet is wider than the cross-sectional area of the exhalation outlet.

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