ANALYZER WITH A POSITIVE DISPLACEMENT PUMP AND A VALVE AND ANALYSIS PROCESS WITH SUCH AN ANALYZER

Abstract

An analyzer and a process analyze a breath sample exhaled by a subject for a predetermined substance, particularly alcohol. An input fluid connection connects an input unit (1) to a measuring chamber (3). A suction fluid connection connects the measuring chamber to a suction chamber unit (5, 6), that is selectively transferrable to a with minimum volume state or a maximum volume state. A sensor (12) measures an amount or a concentration of the substance in the measuring chamber. A drive unit (4, 11) moves a valve (2, 13) for the input fluid connection selectively into a closing or into a releasing end position. The drive unit can also move the suction chamber unit between the two states. The movement of the valve (2, 13) from one end position to the other end position is coupled with a transfer of the suction chamber unit (5, 6) between the two states.

Claims

1. An analyzer for analyzing a gas sample delivered by a subject for a predetermined substance, the analyzer comprises: an input unit configured to input or receive the gas sample; a measuring chamber, the analyzer being configured to at least temporarily provide an input fluid connection between the input unit and the measuring chamber; a sensor configured to measure an indicator of an amount of the substance in a gas located in the measuring chamber and/or an indicator of a concentration of the substance in a gas located in the measuring chamber; a suction chamber unit configured to be selectively transferred into a minimum volume state or a maximum volume state, the analyzer being configured to at least temporarily provide a suction fluid connection between the suction chamber unit and the measuring chamber; a valve configured to be moved into a closing end position in which the valve interrupts the input fluid connection and to be moved into a releasing end position in which the valve releases the input fluid connection; and a drive unit configured to selectively move the valve into the closing end position or into the releasing end position and to selectively transfer the suction chamber unit into the minimum volume state or into the maximum volume state, the drive unit being mechanically coupled to the valve and being mechanically coupled to the suction chamber unit such that: a movement of the valve into the releasing end position is synchronized with a transfer of the suction chamber unit into the minimum volume state, and a movement of the valve into the closing end position is synchronized with a transfer of the suction chamber unit into the maximum volume state; or a movement of the valve into the releasing end position is synchronized with a transfer of the suction chamber unit into the maximum volume state, and a movement of the valve into the closing end position is synchronized with a transfer of the suction chamber unit into the minimum volume state, wherein the analyzer is configured such that a transfer of the suction chamber unit into the maximum volume state causes gas to be sucked out of the input unit through the input fluid connection into the measuring chamber.

2. An analyzer according to claim 1, wherein: the drive unit comprises: an actuator; and a mechanical valve connecting element; the valve comprises a closure part; and a closure part seat; and the valve connecting element mechanically connects the actuator to the closure part.

3. An analyzer according to claim 1, wherein the measuring chamber is located between the input unit and the suction chamber unit.

4. An analyzer according to claim 1, wherein: the drive unit comprises an actuator mechanically coupled to the valve and mechanically coupled to the suction chamber unit; and the suction chamber unit is located between the measuring chamber and the actuator.

5. An analyzer according to claim 1, wherein: the suction chamber unit comprises a suction chamber with variable volume and a chamber modifying element; the drive unit comprises an actuator and a mechanical suction chamber connecting element; the suction fluid connection connects the suction chamber to the measuring chamber; a movement of the chamber modifying element relative to the suction chamber causes the volume of the suction chamber to be changed; and the suction chamber connecting element mechanically connects the actuator to the chamber modifying element.

6. An analyzer according to claim 5, wherein the drive unit comprises: an actuator; and a mechanical valve connecting element; the valve comprises a closure part; and a closure part seat; and the valve connecting element mechanically connects the actuator to the closure part and comprises the suction chamber connecting element.

7. An analyzer according to claim 1, further comprising a volume flow sensor configured to measure an indicator of a volume flow of a gas through the input fluid connection into the measuring chamber, wherein the analyzer is configured to actuate the drive unit to move the valve into the closing end position, the actuation is performed depending on the measured volume flow.

8. An analyzer according to claim 1, further comprising a fluid guide unit, wherein: the valve comprises a closure part; the fluid guide unit surrounds the closure part; an intermediate space is present between the fluid guide unit and the closure part; and the input fluid connection passes through the fluid guide unit and includes the intermediate space.

9. An analyzer according to claim 1, wherein the analyzer is configured such that the transfer of the suction chamber unit into the minimum volume state causes gas to be conveyed through the input fluid connection out of the measuring chamber.

10. An analyzer according to claim 1, further comprising an input fluid guide unit, wherein: the input unit is configured to be connected to the input fluid guide unit; the input fluid connection passes through the input fluid guide unit; and the input fluid guide unit fully or at least partially surrounds the valve.

11. A process for analyzing a gas sample delivered by a subject for a predetermined substance, the process comprising the steps of: providing an analyzer, wherein the analyzer comprises an input unit; a measuring chamber; a sensor; a suction chamber unit which can be selectively transferred into a minimum volume state or a maximum volume state; a valve and a drive unit, wherein the analyzer at least temporarily provides an input fluid connection between the input unit and the measuring chamber and at least temporarily provides a suction fluid connection between the suction chamber unit and the measuring chamber; initially the valve being in a closing end position in which the valve interrupts the input fluid connection; inputting the gas sample into the input unit or receiving the gas sample by the input unit; with the drive unit, moving the valve into a releasing end position in which the valve releases the input fluid connection; with the drive unit, transferring the suction chamber unit into the maximum volume state causing gas to be sucked out of the input unit through the input fluid connection into the measuring chamber; subsequent to the step of transferring the suction chamber unit into the maximum volume state, with the drive unit, transferring the suction chamber unit into the minimum volume state causing gas to be conveyed from the suction chamber unit through the suction fluid connection into the measuring chamber and gas is thereby expelled from the measuring chamber; with the drive unit, moving the valve back into the closing end position; and with the sensor, measuring an indicator of a concentration of the substance in the gas located in the measuring chamber and/or an indicator of an amount of the substance in the gas located in the measuring chamber, wherein either: the step of moving the valve into the releasing end position and the step of transferring the suction chamber unit into the minimum volume state are performed simultaneously, and the step of moving back the valve into the closing end position and the step of transferring the suction chamber unit into the maximum volume state are performed simultaneously, or the step of moving the valve into the closing end position and the step of transferring the suction chamber unit into the minimum volume state are performed simultaneously, and the step of moving back the valve to the releasing end position and the step of transferring the suction chamber unit to the maximum volume state are performed simultaneously.

12. A process according to claim 11, wherein: an event is detected that the input of the gas sample into the input unit is started, wherein the step of moving the valve into the releasing end position is started; if a predefined period of time has elapsed since the gas sample entered the input unit and/or if an opening event has occurred after the start of gas sample input, wherein the opening event depends on an indicator of the volume or amount of the gas sample previously input into the input unit.

13. A process according to claim 11, wherein at least once an indicator of the amount of gas that has so far flowed into the measuring chamber after the start of the step of moving the valve into the releasing end position is measured, and upon the measured amount having reached a predetermined quantity limit, the step of moving the valve back into the closing end position is triggered.

14. A process according to claim 11, wherein before carrying out the process, the suction chamber unit is in the maximum volume state, and the step of transferring the suction chamber unit to the minimum volume state is carried out before the step of transferring the suction chamber unit to the maximum volume state.

15. A process according to claim 11, wherein before carrying out the process, the suction chamber unit is in the minimum volume state, and the step of transferring the suction chamber unit into the maximum volume state is carried out before the step of transferring the suction chamber unit into the minimum volume state.

16. A process according to claim 11, wherein by means of a mechanical coupling of the drive unit with the valve and with the suction chamber unit, the drive unit moves the valve into the one end position and the drive unit transfers the suction chamber unit into the minimum or into the maximum volume state.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0081] In the drawings:

[0082] FIG. 1 is a schematic view showing the mode of operation of an electrochemical sensor;

[0083] FIG. 2 is a perspective view, obliquely from above, of a first embodiment of the analyzer according to the invention;

[0084] FIG. 3 is a perspective view, vertically from above, of the analyzer of FIG. 2;

[0085] FIG. 4 is a cross-sectional view of the analyzer of FIG. 2 and FIG. 3;

[0086] FIG. 5 is another cross-sectional view of the analyzer of FIG. 2 and FIG. 3;

[0087] FIG. 6 is a perspective view of a segment of the analyzer according to the first embodiment comprising the sample inlet, the valve, the rod, the sensor, and the bellows, wherein the measuring chamber is omitted;

[0088] FIG. 7 is a cross-sectional view showing the segment of FIG. 6 with the sensor omitted;

[0089] FIG. 8 is a schematic cross-sectional view of the input fluid connection to the measuring chamber;

[0090] FIG. 9 is a cross-sectional view of a second embodiment of the analyzer according to the invention;

[0091] FIG. 10a is a sectional view through the analyzer with the rod perpendicular to the drawing planes taken along the plane A-A of FIG. 3;

[0092] FIG. 10b is a sectional view through the analyzer with the rod perpendicular to the drawing planes taken along the plane B-B of FIG. 3;

[0093] FIG. 10c is a sectional view through the analyzer with the rod perpendicular to the drawing planes taken along the plane C-C of FIG. 3.

DESCRIPTION OF PREFERRED EMBODIMENTS

[0094] Referring to the drawings, in an embodiment example, the analyzer according to the invention is used to analyze a breath sample exhaled by a subject, in particular a human, for a predetermined substance, in particular breath alcohol. In the case of breath alcohol as the substance, a subject is to be analyzed to determine whether or not alcohol is present in his or her blood above a detection threshold. The subject inputs (delivers) a breath sample into a mouthpiece of the analyzer. If the subject has consumed alcohol and the alcohol in the blood has not yet completely decomposed, the breath sample delivered contains breath alcohol. A part of the delivered breath sample flows into a measuring chamber inside the analyzer. This portion is referred to below as the “measuring chamber sample”. A sensor in or on the measuring chamber checks whether or not this measuring chamber sample contains breath alcohol or any other predetermined substance. The invention can also be applied to another substance that may be present in the exhaled air of a subject or in any other gas that a subject may emit.

[0095] The sensor is capable of generating a signal that correlates with the amount and/or concentration of the given substance in the measuring chamber sample that is in the measuring chamber. Various suitable sensors are known from the prior art, for example electrochemical sensors, photo-optical sensors, photo-acoustic sensors, photo-ionization sensors, and heat tone sensors. Such a sensor can also be applied to the invention.

[0096] The analyzer derives the concentration of breath alcohol in the input breath sample from the measured amount or concentration of breath alcohol in the measuring chamber sample and the amount and/or volume of the measuring chamber sample. For example, the amount and/or volume of the measuring chamber sample is derived depending on the volume of the measuring chamber, which is known by the configuration of the analyzer, and/or by measuring the volume flow into the measuring chamber multiple times and integrating the measured values. If the substance is breath alcohol, a signal-processing evaluation unit of the analyzer or a spatially remote evaluation unit derives the current content of alcohol in the blood of the subject from the breath alcohol concentration in the breath sample.

[0097] As the breath sample passes through the mouthpiece, air first flows from the mouth, then from the upper respiratory tract (upper airway), and then air from the subject's lungs flows through the mouthpiece. To determine if the subject's blood contains alcohol, gas from that portion of the breath sample that originates from the lungs must be tested. Ideally, only gas originating from the subject's lungs will flow into the measuring chamber, and the measuring chamber sample will contain only air from the lungs, but no air from the mouth and upper airway. The following describes how this objective is achieved according to the invention.

[0098] The analyzer of the embodiment comprises an electrochemical sensor 12. By a “sensor” is meant a component that automatically generates a signal, preferably an electrical signal, wherein the generated signal is an indication of the amount and/or concentration of a predetermined substance in the measuring chamber sample. This measuring chamber sample is located in a measuring chamber, wherein the sensor is capable of analyzing this measuring chamber sample in the measuring chamber. An electrochemical sensor triggers a chemical reaction, wherein the chemical reaction depends on the amount and/or concentration of the substance to be analyzed and influences a measurable electrical detection quantity, for example the current intensity or the electrical voltage or the electrical charge or the electrical resistance of a component of the sensor.

[0099] FIG. 1 shows schematically and by way of example the mode of operation of an electrochemical sensor 112 as known from the prior art. The representation of FIG. 1 is not necessarily true to scale. This electrochemical sensor 112 is capable of analyzing a measuring chamber sample Pr for breath alcohol and operates on the principle of a fuel cell with alcohol as the fuel. Features of such a sensor 112 can also be used for the analyzer according to the invention. In one embodiment, the analyzer according to the invention comprises the essential features of such an electrochemical sensor 112.

[0100] The reference number 150 in FIG. 1 denotes a sensor arrangement comprising an electrochemical sensor 112 and a wall 140 for a measuring chamber 103. The wall 140 surrounds the sensor 112 and the measuring chamber 103. In the form of implementation shown, both the wall 140 and the sensor 112 are rotationally symmetrical about the same central axis MA1. Of course, other geometric shapes are also possible.

[0101] The measuring chamber sample Pr to be analyzed, which in the embodiment comes from a breath sample A, flows through an opening Ö.e on the inlet side into the interior of the measuring chamber 103, e.g. by being exhaled or aspirated by a subject or by diffusing into the measuring chamber 103. In one embodiment, the measuring chamber sample Pr flows out of the measuring chamber 103 again through an outlet side opening Ö.a. Thanks to this embodiment, the sensor 112 can quickly examine several measuring chamber samples Pr in succession. It is also possible that there is no outlet-side opening Ö.a and the measuring chamber sample flows out of the measuring chamber 103 again through the inlet-side opening Ö.e.

[0102] The electrochemical sensor 112 comprises: [0103] a measuring electrode 120, which is electrically contacted by a contacting wire 134, [0104] a counter electrode 121, which is electrically contacted by a contacting wire 133, [0105] an electrolyte 128 between the two electrodes 120 and 121, [0106] a connecting wire 122 which electrically connects the two contacting wires 133 and 134 and in which an electrical measuring resistor 129 is arranged, and [0107] a current intensity sensor (amperage meter) 138 that measures the intensity I of the current flowing through the connection wire 122.

[0108] Such an electrochemical sensor 112 is also referred to hereinafter as a membrane electrode electrolyte (MPEE) unit.

[0109] The electrolyte 128 is or comprises an electrically conductive medium, for example sulfuric acid or phosphoric acid or perchloric acid diluted with water. Ions can move in the electrolyte 128. Preferably, a porous membrane provides the electrolyte 128. The electrolyte 128 provides an ionically conductive connection between the measuring electrode 120 and the counter electrode 121, but electrically isolates the two electrodes 120 and 121 from each other.

[0110] The sensor 112 is configured such that the measuring chamber sample Pr reaches only the measurement electrode 120, but not the counter electrode 121. In the example shown, the measurement electrode 120 is located on a wall of the measuring chamber 3, and the wall 140 and the electrolyte 128 prevent a relevant amount of the measuring chamber sample Pr from reaching the counter electrode 121.

[0111] The two contact wires 133 and 134 are electrically conductive and made of a material that is not chemically attacked by the electrolyte 128, for example platinum or gold. The electrodes 120 and 121 are also made of a chemically resistant material, for example also platinum or gold. In many cases, the chemically resistant material of the electrodes 120, 121 additionally acts as a catalyst for a chemical reaction that depends on the substance to be detected and is used for measurement.

[0112] In one embodiment, the electrochemical sensor 112 operates on the principle of a fuel cell. The chemical reaction used for measurement includes the step of oxidizing the breath alcohol in the measuring chamber sample Pr in the measuring chamber 103. Ideally, the entire amount of breath alcohol in the measuring chamber sample Pr is oxidized.

[0113] As a result of the chemical reaction, an electric current flows between the measuring electrode 120 and the counter electrode 121 and thus through the connecting wire 122. The current intensity sensor 138 measures an indicator of the electric charge, i.e. of the total amount of electric current flowing through the connecting wire 122 (principle of coulometry). Generally, electric current flows until all combustible gas, in this case breath alcohol, is oxidized in the measuring chamber 103. For a given volume of measuring chamber sample Pr in measuring chamber 103, the more breath alcohol the measuring chamber sample Pr contains before oxidation, the higher the measured electric charge. The measured electric charge is therefore an indicator of the breath alcohol content in the measuring chamber sample Pr and thus of the alcohol content in the blood of the subject.

[0114] FIG. 2 to FIG. 7 show a first embodiment of an analyzer 100 according to the invention. FIG. 9 shows a second embodiment. FIG. 8 and FIGS. 10a, 10b and 10c are valid for both embodiments.

[0115] FIG. 2 and FIG. 3 show the analyzer 100 according to the first embodiment of the invention in a perspective view, FIG. 4 and FIG. 5 in two cross-sectional views.

[0116] The following additional components are mounted on a frame 9 of the analyzer 100: [0117] a mouthpiece 30 shown only schematically, [0118] a sample inlet 1, [0119] a connecting piece 16, which consists of a smaller part 16.1 and a larger part 16.2, the two parts 16.1, 16.2 being firmly connected to each other, [0120] a sensor arrangement 50 with a measuring chamber 3 and an electrochemical sensor 12, which electrochemical sensor 12 comprises a measuring electrode 20, which is electrically contacted by a contacting wire 34, a counter electrode 21, which is electrically contacted by a contacting wire 33, an electrolyte 28 between the two electrodes 20 and 21, a connecting wire which electrically connects the two contacting wires 33 and 34 and in which an electrical measuring resistor is arranged, and a current intensity sensor (amperage meter) that measures the intensity I of the current flowing through the connection wire, wherein the sensor arrangement 50 can be constructed, for example, comprising features of sensor arrangement 150 as shown in FIG. 1, [0121] an upstream connector 32, which is attached to a wall 40 of the measuring chamber 3 upstream of the measuring chamber 3 and surrounds the part 16.2, [0122] a connection piece 10 on the outflow side, which is attached to the wall 40 of the measuring chamber 3 downstream of the measuring chamber 3, [0123] a linear sliding rod 4, [0124] a connecting sleeve 11 through which the rod 4 is passed, [0125] a bellows 5 acting as the suction chamber unit of the embodiment, [0126] a plate 6 in the bellows 5, the plate 6 acting as the chamber modifying element, [0127] an optional first measuring point MP.1 for a pressure measurement or volume flow measurement described below, [0128] an optional second measuring point MP.2 for another pressure measurement or for this volume flow measurement, [0129] an actuator that can move an object in two opposite directions and whose function is described below, [0130] a schematically shown control unit 60, which receives a signal from the sensor arrangement 50 and from a volume flow sensor or a pressure sensor, respectively, and is configured to control the actuator, and [0131] a power supply unit not shown, for example at least one battery (accumulator), which supplies the actuator with electrical energy.

[0132] The designations “front” and “back” and “upstream” and “downstream” refer to the direction of flow of a gas from sample inlet 1 to bellows 5, i.e. from left to right in FIG. 2 to FIG. 9.

[0133] The mouthpiece 30 is attachable to the sample inlet 1 and removable from the sample inlet 1. In one embodiment, the attached mouthpiece 30 surrounds the sample inlet 1. The mouthpiece 30 has the shape of a funnel, whereby this funnel tapers towards the sample inlet 1 when the mouthpiece 30 is attached. Thanks to this funnel shape, an overpressure is created inside the mouthpiece 30 when a subject supplies (delivers) a breath sample A.

[0134] The mouthpiece 30 belongs to the input unit of the embodiment, the sample inlet 1 and the connecting piece 16 to the input fluid guide unit. An input fluid connection described below passes through the input fluid guide unit and is capable of connecting the mouthpiece 30 to the measuring chamber 3.

[0135] The mouthpiece 30 has an opening through which the breath sample can flow to the sample inlet 1. Preferably, further openings (not shown) are formed into the mouthpiece 30. Breathing air can escape into the environment through these further openings, in particular if excess pressure has developed in the mouthpiece 30. This reduces the risk that, in the event of excess pressure in the mouthpiece 30, part of the breath sample A will return to the subject. A mouthpiece with such openings is described by way of example in DE 10 2017 008 008 A1 (corresponding U.S. Pat. No. 11,474,096 (B2) is incorporated herein by reference).

[0136] The measuring chamber 3 is surrounded by the wall 40 and a cover plate 17. The sensor 12 is arranged under the cover plate 17. In the shown embodiment example, the wall 40 of the sensor arrangement 50 has an outer contour in the form of a cuboid and an inner contour in the form of a cylinder. Other geometric shapes are also possible. The sensor 12 and the measuring chamber 3 are rotationally symmetrical about the same central axis MA. This central axis MA is perpendicular to the drawing plane of FIG. 3 and lies in the drawing planes of FIGS. 4 and FIG. 5.

[0137] In the example shown, the actuator comprises a solenoid 7 and a reset unit in the form of a spring which is supported on the frame 9 and connected to the solenoid 7. The power supply unit, which is not shown, is electrically connected to the solenoid 7. Other configurations of an actuator are also possible, for example an electric motor or a piston-cylinder unit. Even a manual drive may be provided.

[0138] Also shown in the cross-sectional views of FIG. 4 and FIG. 5 are the following components of the analyzer 100: [0139] a valve with a closure part and a closure part seat 13, [0140] a cavity 31 in the form of a tube in the sample inlet 1, [0141] a cavity 15 in the form of a tube inside the connector 16, [0142] the plate 6 in the bellows 5, the plate 6 being firmly connected to the rod 4, [0143] a guide unit 19 which guides the rod 4 linearly along the longitudinal axis of the rod 4 and prevents lateral movement or rotation or canting of the rod 4, [0144] a section through the sensor 12 with the measuring electrode 20, the counter electrode 21 and the electrolyte 28 and [0145] a section through the wall 40 of the measuring chamber 3.

[0146] In addition, FIG. 4 and FIG. 5 show how the linear sliding rod 4 and the connecting sleeve 11 connect the sealing cone (sealing part) 2 to the solenoid 7.

[0147] In the embodiment example, the sealing part 2 has the shape of a sealing cone, and the sealing part seat 13 has the shape of a sealing ring, which is preferably elastic. The diameter of the sealing cone 2 is preferably larger than the diameter of the rod 4, making it possible to make the diameter of the sealing cone 2 as large as possible and the diameter of the rod 4 as small as possible. In any position of the rod 4, the sealing cone 2 is located in the cavity 15. A circumferential gap Sp occurs between the sealing cone 2 and the inner wall of the cavity 15, see FIG. 5 and FIG. 8.

[0148] The sealing element seat (sealing ring) 13 surrounds that end of the rod 4 which is adjacent to the sealing cone 2 and is recessed in a recess in the wall 40. The rod 4 passes through the measuring chamber 3, cf. FIG. 4 and FIG. 5. In the embodiment shown, the longitudinal axis of the rod 4 is perpendicular to the central axis MA of the cylindrical measuring chamber 3 and lies in the drawing planes of FIG. 3, FIG. 4 and FIG. 5. In one embodiment, at least one optional mixing element (not shown) in the form of a flat component is fixedly mounted on the rod 4. The mixing element or each mixing element is located inside the measuring chamber 3 in any position of the rod 4.

[0149] FIG. 6 and FIG. 7 show the sample inlet 1, the valve 2, 13 and the input fluid connection between the sample inlet 1 and the measuring chamber 3 in a perspective view and in a cross-sectional view, respectively. FIG. 8 illustrates the input fluid connection between the sample inlet 1 and the measuring chamber 3 in a schematic cross-sectional view and in a slightly different implementation form from FIG. 2 to FIG. 7.

[0150] In the embodiments shown, the measuring chamber 3 is in fluid connection with the mouthpiece 30 exclusively via the input fluid connection, and only when the valve 2, 13 is fully or at least partially open.

[0151] Two alternative embodiments are also possible, neither of which are shown: [0152] In the first alternative embodiment, the mouthpiece 30 is in fluid connection with the environment via a separate output fluid connection. Preferably, this output fluid connection branches off from the input fluid connection upstream of the valve 2, 13. Preferably, this output fluid connection is closed when the valve 2, 13 is open and is open when the valve 2, 13 is closed. When the output fluid connection is open, breathing air that has been input into the mouthpiece 30 flows through the output fluid connection into the environment, particularly when the valve 2, 13 is closed. This embodiment reduces the risk of gas that the subject has input into the mouthpiece 30 flowing back to the subject. [0153] In the second alternative embodiment, the measuring chamber 3 is in fluid connection with the environment via an outlet fluid connection. The measuring chamber 3 can be flushed out through this outlet fluid connection. Preferably, a valve is arranged in this outlet fluid connection, which is only opened when gas is to be removed from the measuring chamber 3. This embodiment avoids that gas is conducted or conveyed from the measuring chamber 3 into the mouthpiece 30 during flushing of the measuring chamber 3.

[0154] In the illustrations from FIG. 2 to FIG. 7, the bellows 5 is shown in a maximum volume state. The rod 4 couples this state in the first embodiment according to FIG. 2 to FIG. 7 with a state in which the valve 2, 13 is in the closing end position.

[0155] FIG. 9 shows the bellows 5 in a minimum volume state. In the second embodiment according to FIG. 9, the rod 4 couples this state with the state in which the valve 2, 13 is in the closing end position. The same reference signs have the same meanings as in FIG. 2 to FIG. 7.

[0156] FIG. 9 also shows the following components: [0157] a connecting element 26 between the plate 6 and the solenoid 7 and [0158] a bolt (pin) passing through a recess in the connecting element 26 and through a recess in a rod of the solenoid 7.
The wall structure 40 and rod 4 can be tilted or have an angular variation (sensor 12 can rotate) relative to the solenoid 7 about the longitudinal axis of the bolt 27, thanks to the bolt 27.

[0159] FIGS. 10a, 10b and 10c shows three sections through the analyzer 100, with the axis of the rod 4 perpendicular to the respective drawing plane in each section and the viewing direction of solenoids 7 directed towards the sample inlet 1. These three sections apply to both embodiments of the analyzer 100. FIG. 10a shows a section in the plane A-A of FIG. 3, FIG. 10b shows a section in the plane B-B of FIG. 3 and FIG. 10c shows a section in the plane C-C of FIG. 3.

[0160] The following other components of the analyzer 100 are shown in FIG. 6, FIG. 7, and/or FIG. 8: [0161] a tubular recess 18 surrounding the rod 4 and has an approximately triangular cross-sectional area, [0162] a guide unit 19 for the rod 4 and [0163] another sealing ring 14 around the tube 16.

[0164] The cavities 31 and 15 together form a tube that continues into the recess 18. In the embodiment example, the tube 31, 15, the gap Sp and the recess 18 together provide the input fluid connection between the sample inlet 1 and the measuring chamber 3. The sealing cone 2 is movable back and forth between a closing end position, in which the input fluid connection 31, 15, Sp, 18 is interrupted, and a releasing end position, in which the input fluid connection 31, 15, Sp, 18 is released. In the closing end position, shown in the figures, the sealing cone 2 is in fluid-tight contact with the closing element seat (sealing ring) 13. By moving the sealing cone 2 away from the closure element seat 13 and towards the sample inlet 1 (first embodiment) or away from the sample inlet 1 (second embodiment), the sealing cone 2 is moved linearly into the releasing end position.

[0165] When the sealing cone 2 is in the releasing end position or in an intermediate position between the releasing and closing end positions, an input fluid connection 31, 15, Sp, 18 is established between the mouthpiece 30 and the measuring chamber 3. This input fluid connection 31, 15, Sp, 18 passes through the following components: [0166] the tube 31, [0167] the cavity 15, [0168] the gap Sp between the sealing cone 2 and the inner wall of the cavity 15, [0169] the inner space enclosed by the sealing ring 13 and [0170] the recess 18 around the rod 4.

[0171] When the sealing cone 2 is in the closing end position, i.e. rests against the sealing ring 13, this input fluid connection 31, 15, Sp, 18 is interrupted.

[0172] The rod 4 and the connecting sleeve 11 connect the sealing cone 2 with the solenoid 7. The actuator with the solenoid 7 and the spring (not shown) can move the rod 4 linearly in both directions and thus move the sealing cone 2 back and forth between the closing end position and the releasing end position. The rod 4 is guided through the connecting sleeve 11.

[0173] The rod 4, the connecting sleeve 11 and the plate 6 are mechanically connected to each other in such a way that they cannot move relative to each other. The connecting sleeve 11 transmits a movement of the rod 4 to the plate 6. Together with the rod 4, the linear solenoid 7 can also move the connecting sleeve 11 and thus the plate 6 linearly.

[0174] The bellows 5 is mechanically connected to the wall 40 on the side facing the sample inlet 1. The connecting piece 10 surrounds the bellows 5. The plate 6 limits the bellows 5 on the opposite side. A linear movement of the plate 6 towards the sample inlet 1 compresses the bellows 5 and transfers the bellows 5 into the minimum volume state. A linear movement of the plate 6 in the opposite direction pulls the bellows 5 apart and transfers the bellows 5 into the maximum volume state. The bellows 5 is in suction-fluid connection 8 with the measuring chamber 3.

[0175] The solenoid 7, the spring, the bellows 5 and the plate 6 together form a displacement pump. Instead of a solenoid 7, the analyzer 100 can also have another controllable actuator, whereby this actuator can move the rod 4 in both directions and hold it in an end position. A manual actuator may also be provided.

[0176] Instead of a bellows 5 and a plate 6, a piston-cylinder unit (not shown) can also be used, whereby the actuator 7 is capable of moving the piston relative to the cylinder. It is also possible that the other actuator just mentioned is capable of moving the piston of a piston-cylinder unit. It is also possible that an electric motor is capable of moving the rod 4 linearly in both directions.

[0177] The optional first measuring point MP.1 is in fluid connection with the sample inlet 1 or with the cavity 15 and thus in fluid connection with the input fluid connection 31, 15, Sp, 18 just described, which connects the mouthpiece 30 to the measuring chamber 3. Therefore, the first measuring point MP.1 is in fluid connection with the mouthpiece 30 even when the valve 2, 13 is closed. It is also possible that the first measuring point MP.1 is in fluid connection with the recess 18. The optional second measuring point MP.2 is arranged between the measuring chamber 3 and the solenoid 7 and is in fluid connection with the measuring chamber 3.

[0178] Two pressure sensors, which are not shown, measure the pressure at the first measuring point MP.1 and at the second measuring point MP.2, respectively. At each sampling point of a sequence of sampling points, two pressure measurements are performed, respectively. Preferably, these two pressure sensors measure the respective pressure difference with respect to the ambient pressure in the environment of the analyzer 100.

[0179] In one embodiment, the measured values of that pressure sensor which is connected to the first measuring point MP.1 are used to determine approximately the volume flow into the mouthpiece 30 and thus the volume of that amount of breath sample A which has been input into the mouthpiece 30 so far. At least when the valve 2, 13 is closed, this inputted amount of breath sample A essentially causes the pressure inside the funnel-shaped mouthpiece 30 to increase. The slots in the mouthpiece 30 can only partially relieve this excess pressure. The information about the volume of the quantity delivered so far can be used to trigger the operation of opening the valve 2, 13. As already explained, only air from the subject's lungs should enter the measuring chamber 3, but not air from his or her mouth and upper airways. How this desired effect is achieved is described in more detail below

[0180] In one embodiment, the measured values of the pressure sensor connected to the second measuring point MP.2 are used to measure the time course of the pressure in the measuring chamber 3. From this time course of the pressure as well as the volume of the measuring chamber 3, which is known by the configuration of the analyzer 100, an estimated value for the amount of the measuring chamber sample can be derived.

[0181] In a further embodiment, which can be combined with the two embodiments just described, a volume flow sensor not shown derives the difference between the measured pressure at the first measuring point MP.1 and the measured pressure at the second measuring point MP.2. This pressure difference is an indicator of the current volume flow from and into the measuring chamber 3. Optionally, it is also automatically checked whether the valve 2, 13 is tight, i.e. whether it actually interrupts the input fluid connection in the closing position.

[0182] FIG. 8 illustrates how the rod 4 (shown dashed in FIG. 9) is guided. In the example shown, the recess 18 has a triangular cross-section so that a breath sample A can flow past the rod 4 to the measuring chamber 3. Furthermore, the rod 4 is guided linearly by the guide unit 19. Thanks to this guidance, the rod 4 can only move linearly in two directions parallel to its own longitudinal axis, but cannot move laterally or tilt.

[0183] FIGS. 10a, 10b and 10c show the triangular cross-sectional area of cavity 18.

[0184] The following describes how the analyzer 100 collects and analyzes a breath sample A.

[0185] Before use, the analyzer 100 is in an idle state. No mouthpiece 30 is placed on the sample inlet 1. A mechanical or pneumatic spring (not shown) of the actuator is supported on the frame 9 and holds the rod 4 in a position in which the rod 4 has the maximum possible distance from the sample inlet 1 in the first embodiment, and in a position with minimum possible distance from the sample inlet 1 in the second embodiment. The solenoid 7 is deactivated, i.e. no current flows through it. Thanks to the spring, the plate 6 pulls the bellows 5 apart in the first embodiment according to FIG. 2 to FIG. 7, so that the bellows 5 has the maximum volume. In the second embodiment, the plate 6 compresses the bellows 5 in the rest state thanks to the spring, so that the bellows 5 has the minimum volume.

[0186] The sealing cone 2 is in the sealing end position prior to use, and the valve 2, 13 closes the input fluid connection 15, 18 between the sample inlet 1 and the measuring chamber 3. Therefore, the measuring chamber 3 is not in fluid connection with the environment. Particles, substances and other environmental influences can therefore not affect the electrochemical sensor 12 while the analyzer 100 is at rest, and conversely there is little risk of components of the electrolyte 28 leaving the electrochemical sensor 12 or even the measuring chamber 3, for example due to evaporation.

[0187] In one embodiment, the mouthpiece 30 is used to input a single breath sample A and is then discarded. In another embodiment, the mouthpiece 30 is disinfected after the input of a breath sample A and then reused.

[0188] In either embodiment, the mouthpiece 30 is not connected to the remainder of the analyzer 100 until a deployment of the analyzer 100 begins and a subject inputs a breath sample A. Preferably, the event of the mouthpiece 30 being placed on the sample inlet 1 triggers the step of transferring the analyzer 100 from an idle state to a deployed state. For example, a contact switch detects the event that the mouthpiece 30 has been placed on the sample inlet 1.

[0189] During an operation, a subject inputs (delivers) a breath sample A into the attached mouthpiece 30. This breath sample A initially contains exhaled air from the mouth and upper respiratory tract and then exhaled air from the subject's lungs. Ideally, the analyzer 100 examines only exhaled air from the lungs. Therefore, the valve 2, 13 initially remains closed even if the subject has already begun to input a breath sample A into the mouthpiece 30. As mentioned above, the mouthpiece 30 preferably includes several other openings so that the input breath sample A can fully exit into the environment as long as the valve 2, 13 is closed and is not blown into the subject's face.

[0190] In the deployment state, the analyzer 100 automatically detects the occurrence of a predetermined opening event.

[0191] Before the opening event has occurred, the valve 2, 13 is closed and the input air escapes back out of the mouthpiece 30 through the slots or through the output fluid connection, thus ensuring that air actually flows from the subject's lungs into the measuring chamber 3 and, in particular, that no significant amount of air escapes from the mouth and upper airways.

[0192] For example, this opening event has occurred when a predetermined period of time has elapsed since the step of putting on the mouthpiece 30. Or, the opening event has occurred when a predetermined amount of breath sample A has been input into the mouthpiece 30 since the step of putting on the mouthpiece 30, or when the subject has completed the step of inputting a breath sample A. In the second alternative, a sensor measures an indicator of the volume of gas delivered into the mouthpiece 30 or the volume flow of gas into the mouthpiece 30, as described in more detail below.

[0193] Detection that the opening event has occurred triggers the following steps in the first embodiment shown in FIG. 2 through FIG. 7: [0194] A circuit is closed and electric current activates the solenoid 7. [0195] The activated solenoid 7 pushes the rod 4 towards the sample inlet 1 against the force of the spring. [0196] Moving the rod 4 towards the sample inlet 1 causes the sealing cone 2 to be pushed away from the sealing ring (closing element seat) 13 and towards the sample inlet 1. This causes the valve 2, 13 to open, namely to move it into the releasing end position. This releases the input fluid connection described above between the input unit (the mouthpiece 30 and the sample inlet 1) and the measuring chamber 3. [0197] Moving the rod 4 also causes the plate 6 to compress the bellows 5. [0198] Because the bellows 5 is compressed, gas flows from the bellows 5 through the inlet fluid connection 8 and into the measuring chamber 3. This pushes existing gas from the measuring chamber 3 through the inlet fluid connection 18, 15 and out of the analyzer 100 through the sample inlet 1. As a result, the measuring chamber 3 is purged. The purged gas in the measuring chamber 3 may be from a previous input. [0199] The pressure caused by compressing the bellows 5 is much greater than the pressure caused by inputting the breath sample A into the mouthpiece 30. Therefore, no significant amount of the input breath sample A flows into the input fluid connection while the volume of the bellows 5 is still being reduced. [0200] Once the bellows 5 is fully compressed, no more gas is forced out of the measuring chamber 3 through the input fluid connection. The valve 2, 13 is open and gas can be sucked or flow from the mouthpiece 30 through the input fluid connection into the measuring chamber 3.

[0201] As soon as a closing event is detected, the following steps are triggered: [0202] The rod 4 is again pushed away from the sample inlet 1 until the valve body 2 reaches the closure element seat 13. For example, solenoid 7 is de-energized again and the spring moves rod 4 away from sample inlet 1. [0203] As soon as the valve body 2 reaches the closing element seat 13, the input fluid connection 31, 15, Sp, 18 is closed again, and the measuring chamber 3 is separated fluid-tightly from the mouthpiece 30 and from the environment. [0204] Moving the rod 4 away from the sample inlet 1 also causes the plate 6 to pull the bellows 5 apart. Pulling the bellows 5 apart creates a negative pressure. The negative pressure causes gas to be drawn from the mouthpiece 30 through the cavity 31 in the sample inlet 1 and the input fluid connection 31, 15, Sp, 18 in the connector 16 into the measuring chamber 3. The amount of gas drawn into the measuring chamber 3 by this negative pressure belongs to the measuring chamber sample. [0205] Moving the rod 4 further causes the optional mixing element or each optional mixing element on the rod 4 to move through the measuring chamber 3, thereby mixing the gas in the measuring chamber 3 to some degree. [0206] As soon as the plate 6 has completely pulled the bellows 5 apart, the bellows 5 has reached its maximum volume. The valve 2, 13 has again reached the closing end position.

[0207] The electrochemical sensor 12 analyzes the gas sample in the measuring chamber 3, for example as described with reference to FIG. 1. Here, the measuring electrode 20 oxidizes the breath alcohol present in the measuring chamber 3. The measuring chamber sample is in the measuring chamber 3 until the rod 4 is pushed towards the sample inlet 1 again, thereby compressing the bellows 5. The time interval between [0208] the event that the bellows 5 is fully extended and the valve 2, 13 is closed, and [0209] the event that is started to compress the bellows 5 again, is available to the electrochemical sensor 12 for analysis, in particular for oxidation, of the measuring chamber sample. During this period, the valve 2, 13 is closed. As a rule, this time period is sufficient to completely oxidize alcohol in the measuring chamber sample.

[0210] The second embodiment according to FIG. 9 has the following deviations from the first embodiment according to FIG. 2 to FIG. 7: [0211] The sealing ring 13 is located upstream of the sealing cone 2, while in the first embodiment the sealing ring 13 is located downstream of the sealing cone 2. [0212] At rest, the spring, which is not shown, holds the rod 4 in a position in which the rod 4 is the smallest possible distance from the sample inlet 30. [0213] The activated solenoid 7 pulls the rod 4 away from the sample inlet 1 against the force of the spring. [0214] Moving the rod 4 away from the sample inlet 1 causes the sealing cone 2 to move away from the sealing ring 13 and toward the measuring chamber 3, thereby opening the valve 2, 13. [0215] In addition, moving the rod 4 away from the sample inlet 1 causes the plate 6 to pull the bellows 5 apart. [0216] Because the bellows 5 is pulled apart, gas flows through the input fluid connection 31, 15, Sp, 18 into the measuring chamber 3. The gas that flows into the measuring chamber 3 in this manner belongs to the measuring chamber sample. [0217] The closing event triggers the step of pushing the rod 4 back towards the sample inlet 1, for example by the spring. [0218] The sealing cone 2 is moved away from the measuring chamber 3 and towards the sealing ring 13. As soon as the sealing cone 2 has reached the sealing ring 13, the valve 2, 13 is closed again. [0219] Moving the rod 4 toward the sample inlet 1 also causes the plate 6 to push the bellows 5 back together. The pushing together of the bellows 5 causes an overpressure. This overpressure causes gas, and thus the measuring chamber sample, to be pushed out of the bellows 5 through the suction fluid connection 8 and into the measuring chamber 3. This causes gas to be pushed out of the measuring chamber 3 through the input fluid connection 15, Sp, 18 and through the cavity 31 into the sample inlet 1. This flushes the measuring chamber 3.

[0220] In the second embodiment according to FIG. 9, the following time period is available for the sensor 12 to analyze the measuring chamber sample: the time period between [0221] the event that the bellows 5 is fully extended, and [0222] the event that the collapsing of the bellows 5 is started again.
During this period, the valve 2, 13 is fully open.

[0223] In order for the electrochemical sensor 12 to reliably analyze a gas and thus also the measuring chamber sample in the measuring chamber 3 for the presence of breath alcohol and to measure the amount or concentration of breath alcohol in the measuring chamber 3, it should be known at least approximately what amount (mass) of the breath sample A is in the measuring chamber 3 during the analysis, thus what amount the measuring chamber sample has. Based on the design of the analyzer 100, the volume of the measuring chamber 3 is known. The difference between the maximum volume and the minimum volume of the bellows 5 is also known by design. Ideally, only air from the subject's lungs flows into the measuring chamber 3, but no air from the mouth and upper airways, so that the measuring chamber sample consists only of air from the lungs.

[0224] In both of the above-described embodiments, gas is drawn into the measuring chamber 3 by pulling the bellows 5 apart, thereby changing it from the minimum volume state to the maximum volume state. The difference between the maximum volume and the minimum volume of the bellows 5 is in many cases equal to the volume of breathing air drawn into the measuring chamber 3 from the mouthpiece 30.

[0225] In addition, during a period of time when the valve 2, 13 is or will be open and at the same time the bellows 5 is not moved, gas may flow into the measuring chamber 3, for example because the subject continues to exhale further or by diffusion. In many cases, however, the amount of gas that flows into the measuring chamber 3 when the bellows 5 is not moving can be neglected.

[0226] In one embodiment, a pressure sensor that is in fluid connection with the measuring position MP.1 measures the time course of an indicator of the overpressure in the mouthpiece 30 relative to the ambient pressure. From this time course of pressure, it is possible in some cases to derive which volume of breathing gas flows into the measuring chamber 3 in a period of time in which the valve 2, 13 is or becomes open and at the same time the bellows 5 is not moved.

[0227] In one embodiment, a volume flow sensor measures the difference between the pressures at the two measuring points MP.1 and MP.2 and determines the volume flow from this. By integrating over a certain period of time, the volume flowing through the input fluid connection 31, 15, Sp, 18 into the measuring chamber 3 during this period of time is derived from the volume flow. This time span is, for example, equal to the time span in which the valve 2, 13 is open and at the same time the bellows 5 is not moved. Optionally, the measuring time period additionally comprises the time period in which the valve body 2 is moved. It is also possible that this measurement time period also includes the time period in which the bellows 5 is pulled apart, so that the volume flow sensor is also used to measure which volume is sucked into the measuring chamber 3.

[0228] To deliver a valid breath sample A, the subject must exhale into the mouthpiece 30 during the procedure just described and thereby deliver the breath sample A at least until the bellows 5 is fully extended. If the subject cancels the delivery of the breath sample A before then, a corresponding message is preferably output in a form that can be perceived by a human. Preferably, the patient can then deliver another breath sample A.

[0229] Various embodiments of how the opening event may be determined are described below. As mentioned earlier, the valve 2, 13 is then started to move to the releasing end position when the opening event is detected. Ideally, the opening event has occurred when air from the subject's lungs has reached the mouthpiece 30. [0230] In one embodiment, the opening event has occurred when a predetermined period of time has elapsed since the mouthpiece 30 was placed on the mouthpiece. [0231] In another embodiment, an approximate measurement is made of the amount of exhaled air the subject has input into the mouthpiece 30 since the mouthpiece 30 was put in place. As explained above, in one embodiment, a pressure sensor in fluid connection with the first measurement point MP.1 measures an indicator of the positive pressure in the mouthpiece 30 relative to the ambient pressure several times in succession. An estimated value for the previously input volume is derived at least once from the measured values for the pressure difference. When the volume delivered so far reaches a predetermined volume threshold, the opening event has occurred. This volume threshold is preferably equal to the average volume of the mouth and upper airway of an adult. [0232] Another embodiment can be used, in particular, in conjunction with the output fluid connection described above and not shown, namely when the output fluid connection connects the mouthpiece 30 to the environment. As long as the valve 2, 13 is closed, the respiratory air that the subject has input into the mouthpiece 30 is passed through the output fluid connection to the environment. The volume flow sensor described above with the two measuring positions MP.1 and MP.2 measures the volume flow through the input fluid connection 31, 15, Sp, 18 and the output fluid connection. The volume delivered so far is derived from the measured volume flow. As soon as the volume delivered so far reaches the volume threshold, the opening event has occurred.

[0233] The step of starting the movement of the valve 2, 13 back into the closing end position is triggered by the closing event. Various configurations are possible as to when the closing event has occurred: [0234] In one embodiment, the closing event occurs as soon as the valve 2, 13 has reached the releasing end position. The valve 2, 13 thus remains in the releasing end position for only a very short period of time, ideally for only one instant. Gas is drawn into the measuring chamber 3 exclusively by the bellows 5 being pulled apart, i.e. being transferred from the with minimum volume state into the maximum volume state. The quantity, for example the mass, of the measuring chamber sample that enters the measuring chamber 3 is determined by the difference between the maximum volume and the minimum volume of the bellows 5. [0235] In another embodiment, it is automatically determined when the chemical reaction in the measuring chamber 3 has ended. At the end of the chemical reaction, all breath alcohol in the measuring chamber 3 is oxidized. To determine this event, the time course of the signal generated by the sensor 12 is determined. If the signal from the sensor 12 remains approximately constant, the chemical process is complete. The completion of the chemical process acts as the closing event.

[0236] This other embodiment can be used in particular in conjunction with the second embodiment (FIG. 9). This is because in the second embodiment, the closing event causes the bellows 5 to be compressed and the measuring chamber sample to be forced out of the measuring chamber 3, thereby flushing the measuring chamber 3. Thus, by this time, the analysis of the measuring chamber sample must be completed. Before this, the input fluid connection is established.

[0237] In the embodiments described so far, breathing air, which ideally comes only from the subject's lungs, enters the measuring chamber 3 and functions there as the measuring chamber sample to be analyzed. It is possible that a preliminary sample is additionally drawn into the measuring chamber 3 in advance and expelled from the measuring chamber 3 again before air from the subject's lungs enters the measuring chamber 3. The bellows 5 is thus pulled apart and compressed again twice in order to test the same subject for alcohol. As a rule, this presample consists predominantly of air originating from the mouth and/or the upper respiratory tract of the subject. The measuring chamber 3 is rinsed out with the aid of the preliminary sample. In one embodiment, the level of breath alcohol in the mouth and/or in the upper respiratory tract of the subject is also determined at least approximately. In another embodiment, the presample is used to bring the electrodes 20, 21 of the sensor 12 to the temperature of the breath sample A. Typically, the breath sample A has a higher temperature than the ambient air. This embodiment increases the reliability of the measurement result in some cases. The two embodiments just described can be combined.

[0238] The bellows 5 is in fluid connection with the measuring chamber 3 through the inlet fluid connection 8. The action of compressing the bellows 5 causes gas to be forced into the measuring chamber 3 through the inlet fluid connection 8, thereby purging the measuring chamber 3. In the embodiments described thus far and shown in the figures, the gas that is forced out of the measuring chamber 3 is forced into the mouthpiece 30 through the input fluid connection 31, 15, Sp, 18.

[0239] In a different and not shown embodiment, the analyzer additionally comprises an outlet fluid connection. The measuring chamber 3 is in fluid connection with the environment via this outlet fluid connection. A three-way valve can optionally be brought into one of the following three positions: [0240] to an inlet position where the three-way valve clears the inlet fluid connection 31, 31, 15, Sp, 18 while blocking the outlet fluid connection, [0241] to an outlet position in which the three-way valve releases the outlet fluid connection while blocking the input fluid connection 31, 31, 15, Sp, 18, and [0242] optionally to a blocking position in which the three-way valve blocks both fluid connections.

[0243] During the process of pulling the bellows 5 apart, the three-way valve is in the inlet position so that gas can flow through the inlet fluid connection 31, 15, Sp, 18 into the measuring chamber 3. During the process of compressing the bellows 5, the three-way valve is in the outlet position so that gas can flow out of the measuring chamber 3 through the outlet fluid connection. This embodiment results in gas being expelled into the environment rather than into the mouthpiece 3 when the measuring chamber 3 is purged. Preferably, the three-way valve is in the closed position while the bellows 5 is not moved.

[0244] In one embodiment, the opening event causes the three-way valve to move to the inlet position. In a preferred embodiment, the closing event causes the three-way valve to move to the outlet position.

[0245] While specific embodiments of the invention have been shown and described in detail to illustrate the application of the principles of the invention, it will be understood that the invention may be embodied otherwise without departing from such principles.

LIST OF REFERENCE SIGNS

[0246]

TABLE-US-00001 1 Sample inlet, surrounds tube 31, belongs to input fluid guide unit 2 Linearly movable sealing cone, acting as a valve body and as a closure part, movable relative to the valve body seat 13, arranged upstream (first embodiment) or downstream (second embodiment) of the valve body seat 13 3 Measuring chamber, receives a sample flowing in through the sample inlet 1, surrounds the sensor 12, is surrounded by the wall 40 4 Rod, connects the sealing cone 2 with the solenoid 7, guided through the connecting sleeve 11 and guided through the measuring chamber 3, belongs to the mechanical connecting element 5 Bellows capable of generating a negative pressure and a positive pressure in the measuring chamber 3, is pulled apart and compressed by the plate 6, acts as a suction chamber 6 Plate, is able to pull apart and compress the bellows 5, acts as a chamber modifying element 7 Solenoid, linearly moves rod 4 parallel to its longitudinal axis, longitudinal axis, acts as actuator 8 Suction fluid connection between the measuring chamber 3 and the bellows 5 9 Frame (rack) on which the sample inlet 1, the wall 40, the sensor 12 and the solenoid 7 are mounted 10 Outflow-side connection piece, attached to measuring chamber 3 11 Connecting sleeve, through which the rod 4 is passed, firmly connected to the rod 4 and to the plate 6, belongs to the mechanical connecting element 12 Electrochemical sensor in the measuring chamber 3, comprises electrodes 20 and 21 and electrical contacts 33, 34, is capable of determining an indicator of the concentration of breath alcohol in the measuring chamber sample 13 Sealing ring around the rod 4, acts as a valve body seat and thus as a closure part seat for the sealing cone (valve body) 2, arranged downstream (first embodiment) or upstream (second embodiment) from the sealing cone 2 14 Further sealing ring, arranged around the tube 16 15 Cavity in connecting piece 16 16 Connecting piece between the sample inlet 1 and the sealing cone 2, surrounds the cavity 15, comprises the parts 16.1 and 16.2, belongs to the input fluid guide unit 16.1 Smaller part of the connector 16 16.2 Larger part of the connector 16 17 Cover plate for the sensor 12 18 Recess belonging to an input fluid connection between the cavity 15 and the measuring chamber 3 19 Guide unit that guides the rod 4 linearly 20 Measuring electrode of the sensor 12, is contacted by the electrical contact 34 21 Counter electrode of the sensor 12, is contacted by the electrical contact 33 25 Stop element on the sample inlet 1, limits a movement of the mouthpiece 30 towards the measuring chamber 3. 26 Connecting element between the plate 6 and the solenoid 7 27 Bolt, passing through a recess in the connecting element 26 and in a rod 4 of the solenoid element 7 28 Electrolyte between the two electrodes 20 and 21 30 Funnel-shaped mouthpiece, directs a breath sample A into the sample inlet 1 31 Tube inside the sample inlet 1 32 Inlet-side connection piece, attached to the measuring chamber 3, surrounds the larger part 16.2 33 Electrical contacting of the counter electrode 21 34 Electrical contacting of the measuring electrode 20 40 Wall of measuring chamber 3 50 Sensor arrangement, comprises a sensor 12 and a measuring chamber 3 60 Control unit 100 Analyzer, includes mouthpiece 30, frame 9, sample inlet 1, measuring chamber 3, sensor 12, rod 4, valve 2, 13, actuator with solenoid 7 and connecting sleeve 11 103 Measuring chamber, receives a sample flowing in through the sample inlet side opening Ö.e, surrounds the sensor 112, is surrounded by the wall 140 112 Electrochemical sensor in the measuring chamber 103, comprises electrodes 120 and 121 and electrical contacts 133, 134, is capable of determining an indicator of the concentration of breath alcohol in the measuring chamber sample Pr 120 Measuring electrode of the sensor 112, is contacted by the electrical contact 134 121 Counter electrode of the sensor 112, is contacted by the electrical contact 133 122 Electrical connection between contacts 133 and 134 128 Electrolyte between the two electrodes 120 and 121 129 Electrical measuring resistance between the two electrodes 120, 121 133 Electrical contacting of the counter electrode 121 134 Electrical contacting of the measuring electrode 210 138 Current sensor, measures the strength of the current flowing through the electrical connection 122 140 Wall of measuring chamber 103 150 Sensor arrangement, comprises a sensor 112 and a measuring chamber 103 A Breath sample to be analyzed for breath alcohol contains the measuring chamber sample, which is aspirated into the measuring chamber 3 MA Coinciding center axis of the measuring chamber 3 and the sensor 12 MA1 Coinciding center axis of the measuring chamber 103 and the sensor 112 MP.1 First measuring point, is in fluid connection with the cavity 15 or recess 18 and thereby in fluid connection with the mouthpiece 30 MP.2 Second measuring point, is in fluid connection with the measuring chamber 3 Ö.a Outlet-side opening in the housing, through which the measuring chamber sample Pr flows out of the measuring chamber 103 Ö.e Opening on the inlet side in the housing, through which the measuring chamber sample Pr flows into the measuring chamber 103 Pr Measuring chamber sample, which is that part of the breath sample emitted by the subject that enters the measuring chamber 103 Sp Circumferential gap between the sealing cone 2 and the inner wall of the cavity 15