RU218080U1 - Ethanol vapor analyzer in exhaled air - Google Patents

Abstract

The utility model relates to instrument engineering, namely, to an analyzer of the composition of exhaled air by the spectral characteristics of the gas mixture, and can be used in the construction of access control systems for instant contactless determination of the content of ethyl alcohol vapor in exhaled air, identifying the fact and degree of intoxication and blocking access. An analyzer containing a housing (1) and an infrared spectrophotometer (7) and a signal processing module installed in the housing. Infrared spectrophotometer (7) includes a spectrophotometer body configured to pass incoming gas through it, as well as an optical assembly for supplying and receiving infrared radiation. The housing (1) is provided with two front panels (2, 3) oriented at an angle to each other, while in each front panel (2, 3) there is an opening (4, 5) for the incoming gas, aligned with the housing of the infrared spectrophotometer (7 ). The technical result is an increase in the speed of monitoring the composition of the exhaled air of a plurality of users. 4 w.p. f-ly, 4 ill.

Description

[01] Field of technology

[02] The utility model relates to instrumentation, namely, to an analyzer of the composition of exhaled air by the spectral characteristics of the gas mixture and can be used in the design of access control systems for instant contactless determination of the content of ethyl alcohol vapor in exhaled air, identifying the fact and degree of intoxication and blocking access .

[03] State of the art

[04] Analyzers of the composition of exhaled air (alcotesters), using infrared radiation, have a number of advantages in relation to analogues with electrochemical sensors. The devices have a resource of about 100,000 hours, do not depend on the number of measurements (determined by the resource of light and photodiodes) and are not subject to sensitivity degradation during operation.

[05] When using breathalyzers to access various objects, their work is carried out in a streaming mode, which requires a high speed of the device.

[06] The closest analogue of the utility model is an analyzer for determining the content of ethanol vapor in exhaled air, described in the publication of US application US 2011283770, 24.11.2011. The analyzer has a housing with an opening for supplying the incoming gas. An infrared spectrophotometer is placed inside the analyzer case, including a spectrophotometer case (measuring cell) forming a channel for the passage of incoming gas, as well as an optical unit for supplying infrared radiation to the measuring cell and receiving said radiation. In addition, the device contains a signal processing module (microprocessor) connected to an infrared spectrophotometer.

[07] The disadvantage of this analogue and other similar devices is the low speed. This shortcoming is the main technical problem that the utility model is aimed at solving.

[08] Disclosure of the utility model

[09] The technical result of the utility model is to increase the speed of monitoring the composition of the exhaled air of many users.

[010] This problem is solved, and the technical result is achieved in the utility model due to the fact that the exhaled air analyzer contains a housing and an infrared spectrophotometer and a signal processing module installed in the housing. The infrared spectrophotometer includes a spectrophotometer housing configured to pass incoming gas through it, as well as an optical assembly for supplying and receiving infrared radiation. In this case, the body of the analyzer is provided with two front panels oriented at an angle to each other, and each front panel has an opening for the incoming gas, which is aligned with the body of the infrared spectrophotometer.

[011] In addition, the specified technical result is achieved in particular cases of implementation of the utility model due to the fact that

[012] - the body of the spectrophotometer is made in the form of a cuvette installed with the possibility of infrared radiation passing through its internal space, while the cuvette has two side inlets aligned with the openings of the analyzer body and two outlet gas ducts aligned with the outlets made on the rear panel of the analyzer body ;

[013] - the cuvette is made vertical, with elongated side inlets, while the walls of the cuvette are made of printed circuit boards and equipped with heaters;

[014] - the optical assembly of the infrared spectrophotometer has a water channel (14) formed by an LED, a photodetector, a light filter and a lens, as well as an alcohol channel formed by an LED, two photodetectors, two light filters, two lenses and a beam splitter plate;

[015] - in each opening of the body of the analyzer, an incoming gas heating module is additionally installed, including a frame in which a heater with a thermistor and a gas-permeable heat exchanger is placed, made in the form of a gyroid or grid;

[016] - the inlet gas heating module is removable and can be replaced with a through frame;

[017] - the signal processing module is made in the form of a printed circuit board on which a temperature and humidity sensor is installed;

[018] - a graphic display is installed on each front panel of the case,

[019] - the analyzer additionally includes light and sound indicators installed in the housing and a module for interaction with the access control and management system.

[020] Unlike analogues, the claimed analyzer design uses a housing with two openings for incoming gas (exhaled air) located on different front panels oriented at an angle to each other. This increases the convenience and speed of monitoring the composition of the exhaled air of users when working with large flows of people. Thus, the analyzer makes it easy to control both direct and oncoming flows of people moving along the aisle (on the side of which the device is installed). When passing by the device in both directions, users exhale either to the right-forward towards the first front panel, or to the left-forward towards the second front panel. This greatly speeds up the ethanol vapor check compared to devices with a single inlet.

[021] In addition, in the design, due to the means of heating the incoming gas and the body (cuvette) of the spectrophotometer, the operating temperature range is extended. The design of the cuvette increases the vibration resistance of the device and the speed of its response, and also simplifies the maintenance of the device. At the same time, the design of the optical system ensures accurate measurements. All this also has a positive impact on the speed of user control.

[022] Brief Description of the Drawings

[023] The utility model is illustrated by figures, where:

In FIG. 1 shows a general view of the analyzer from the front and rear sides,

In FIG. 2 shows the analyzer in section,

In FIG. 3 shows the construction of a spectrophotometer with a cuvette,

In FIG. 4 shows the design of the heating module and replaceable frame,

[024] The structural elements are indicated in the figures by the following positions:

1 - body,

2, 3 - front panels (glasses) of the case,

4, 5 - body openings for supplying incoming gas,

6 - incoming gas heating module,

7 - infrared spectrophotometer,

8 - cuvette (body) of the spectrophotometer,

9 - side entrance of the cuvette,

10 - outlet gas duct of the cuvette,

11, 12 - body outlets,

13 - rear panel of the case,

14 - water channel,

15 - water channel LED,

16 - water channel photodetector,

17 - light filter of the water channel,

18 - water channel lens,

19 - alcohol channel,

20 - alcohol channel LED,

21, 22 - alcohol channel photodetectors,

23, 24 - light filters of the alcohol channel,

25, 26 - alcohol channel lenses,

27 - beam splitter plate of the alcohol channel,

28 - front panel frame,

29 - heating module frame,

30 - heater,

31 - heat exchanger

32 - heater contacts

33 - framing,

34, 35 - information graphic displays.

[025] Implementation of the utility model

[026] The claimed analyzer (see Fig. 1) includes a vertical housing (1) with side walls in the form of panels: two front panels (2, 3) and one rear panel (13). The front panels (2) and (3) have openings (4, 5) for supplying exhaled air (inlet gas) to the housing (1). In these openings (4, 5) there is one module for heating the incoming gas (6).

[027] Inside the housing (1), behind the heating modules (6), an infrared spectrophotometer (7) is placed, including the housing and the optical assembly (see Fig. 1). The body of the spectrophotometer is made in the form of a cuvette (8), which preferably has the shape of a prism and is adapted for passing through it a transverse flow of incoming gas (see Fig. 2). On the walls of the cuvette (8) there are two side inlets (9) located opposite the openings (4, 5) of the body (1), as well as two outlet gas ducts (10) located opposite the two outlet holes (11, 12) made on the rear panels (13) of the body (1) of the analyzer.

[028] The walls of the cuvette (8) are made according to standard printed circuit board technology with thermistors and are equipped with heating elements that prevent water from condensing at low temperatures.

[029] The optical assembly of the spectrophotometer (7) (see Fig. 2) includes a water channel (14), consisting of an LED (15), a photodetector (16), a light filter (17), and a lens (18), as well as an alcohol channel (19), consisting of an LED (20) with a Peltier element, two photodetectors (21, 22) with a Peltier element, two light filters (23, 24), two lenses (25, 26), a beam splitter plate (27). Water (14) and alcohol (19) channels of the optical assembly run along the cuvette (8) perpendicular to the incoming gas flow. The lenses (18, 25, 26) can be provided with heaters to prevent water condensation.

[030] The inlet gas heating module (6) (see Fig. 3, 4) is installed in the frame (28) fixed in the opening (4, 5) on the front panel (2, 3) of the housing (1). The module (6) includes a plastic frame (29), as well as a heater (30) and a heat exchanger (31) installed in the frame. The heater (30) is made according to the technology of printed circuit boards and is equipped with a thermistor (not shown) and contacts (32) that provide heating of the heat exchanger (31). The heat exchanger (31) is made gas-permeable and can be manufactured using selective laser sintering (SLS) technology in the form of a gyroid or by stamping from a metal mesh, or in another way that provides a sufficiently low resistance to the inlet gas flow with sufficient heating. When the analyzer is operating at positive (plus) temperatures, the inlet gas heating module (6) can be removed by the user and replaced by a through frame (33) of the opening.

[031] The analyzer housing (1) also houses a signal processing module (not shown) connected to the spectrophotometer. This module is a printed circuit board with an ambient temperature and humidity sensor. The signal processing module can also be equipped with a thermal stabilization unit for more stable operation of the device.

[032] Two information graphic displays (34, 35) mounted on the front panels (2, 3) of the housing (1) are connected to the signal processing module. Displays (34, 35) increase the comfort of observing commands and analysis results appearing on the displays by people passing by the instrument from different directions.

[033] The design of the analyzer can also be provided with a module for interaction with the access control system (ACS), as well as light and sound indicators for detecting a given concentration of ethanol vapors (not shown).

[034] The device operates as follows.

[035] The described analyzer is installed on a stable base on the side, to the right or to the left, of the aisle along which people controlled for alcohol content move. It is possible to install the device directly on an automated or mechanized turnstile. It is possible to install in such a way that the device is in the field of view of persons controlling the order of access to the object. The device is designed in such a way that it is possible to perform analysis when exhaling into one of the two receiving windows, both on the right and on the left, which is convenient for personnel control both at the entrance and at the exit when the device is installed on one side of the passage.

[036] Connected to the network and means of communication with the ACS system of the enterprise (if any and if necessary), after about 5 minutes after switching on, the device warms up the walls and protective glasses of the cuvette, the through-flow heat exchanger to the specified temperatures and sends a signal of readiness to the ACS system . The controlled person, passing by the rack with the device installed on it, stops and exhales into one of the receiving windows of the device (cuvettes). The device analyzes for about 0.5-1 second and, depending on the concentration of alcohol in the exhaled air, performs the following actions:

[037] When the concentration of alcohol vapor is less than the specified one, it sounds an audible signal, turns on the green light indication, displays the measured concentration on the display, transmits data to the access control system, unlocks the turnstile, if any.

[038] When the concentration of alcohol vapor is higher than the specified one, it gives a loud intermittent sound signal, turns on the red light indication, displays the measured concentration on the display, transmits data to the ACS system, blocks the turnstile, if any, transmits a signal to the security post, if necessary, and the presence of such.

[039] 1 second after the measurement, the instrument is ready for the next one.

Claims (5)

1. Ethanol vapor analyzer in exhaled air, containing a housing (1) and an infrared spectrophotometer (7) and a signal processing module installed in the housing (1), while the infrared spectrophotometer (7) includes a spectrophotometer housing configured to pass incoming gas through it , as well as an optical unit for supplying and receiving infrared radiation, characterized in that the body (1) of the analyzer is equipped with two front panels (2, 3) oriented at an angle to each other, while each front panel (2, 3) has opening (4, 5) for the incoming gas, combined with the body of the infrared spectrophotometer (7). 2. The analyzer according to claim 1, characterized in that the body of the spectrophotometer is made in the form of a cuvette (8) installed with the possibility of infrared radiation passing through its internal space, while the cuvette (8) has two side entrances (9) aligned with openings (4, 5) of the body (1) of the analyzer, and two outlet gas ducts (10) aligned with the outlets (11, 12). 3. The analyzer according to claim 2, characterized in that the cuvette (8) is made vertical, with elongated side inlets (9), while the walls of the cuvette (8) are made of printed circuit boards and are equipped with heaters. 4. The analyzer according to claim 1, characterized in that the optical unit of the infrared spectrophotometer has a water channel (14) formed by an LED (15), a photodetector (16), a light filter (17) and a lens (18), as well as an alcohol channel (19 ) formed by an LED (20), two photodetectors (21, 22), two light filters (23, 24), two lenses (25, 26) and a beam splitter (27). 5. The analyzer according to claim 1, characterized in that the signal processing module is made in the form of a printed circuit board on which a temperature and humidity sensor is installed.

Images