DE102023200141A1 - Anthropomorphic model for simulating driver gas emissions and method for simulating driver gas emissions - Google Patents

Abstract

Anthropomorphic model (100) for simulating gas emissions from a driver, the anthropomorphic model (100) comprising:
• a head (101);
• a torso (102);
• at least one gas outflow unit, wherein the gas outflow unit is designed to simulate human breath and/or other body exhalations, wherein the gas outflow unit comprises at least one gas outflow opening (103).

Description

The invention relates to an anthropomorphic model for simulating gas emissions from a driver. The invention further relates to a method for simulating gas emissions from a driver.

The following definitions apply to the entire disclosure content.

Under Regulation (EU) 2019/2144 It is stipulated that motor vehicles must be equipped with a device for installing an alcohol-sensitive immobilizer. In order to be able to test the functionality of such devices under conditions that are as realistic as possible, a test body is advantageous, with the help of which a person and their breathing can be simulated.

The state of the art already includes a breathing simulator developed by Paragon Space Development Corporation that can recreate the inhalation and exhalation cycle at user-defined breathing frequencies, while controlling the gas temperature, humidity, oxygen and carbon dioxide content.

However, other factors can play a decisive role in the testing of the aforementioned devices, for example that an anthropomorphic model releases additional gases in defined quantities and can optionally move in order to be able to demonstrate the functionality of the device.

The object of the invention was to provide an anthropomorphic model for simulating gas emissions from a driver.

The subject matters of the independent claim and the subordinate claim each solve this problem.

• • einen Kopf;
• • einen Torso;
• • mindestens eine Gasausströmungseinheit, wobei die Gasausströmungseinheit ausgebildet ist den menschlichen Atem und/oder andere Körperausdünstungen nachzubilden, wobei die Gasausströmungseinheit mindestens eine Gasausströmungsöffnung umfasst.

In one aspect, the invention provides an anthropomorphic model for simulating gas leakage from a driver, the anthropomorphic model comprising:

• • a head;
• • a torso;
• • at least one gas outflow unit, wherein the gas outflow unit is designed to simulate human breath and/or other body exhalations, wherein the gas outflow unit comprises at least one gas outflow opening.

The model can be a physical object, for example the model can include parts of a dummy, as known from crash tests, or can also be such a dummy. The torso can have the anthropomorphic appearance of a chest, a stomach, a back, a pelvis or a combination of chest, stomach, back and/or pelvis. The torso does not necessarily have to have an anthropomorphic appearance, but can also be designed in the form of a rod, for example.

In order to recreate a driver's sitting position, it is advantageous for the anthropomorphic model to be equipped with a torso and a head. The head can, for example, be attached to the torso in a movable manner so that it can be aligned in different positions. The alignment can, for example, be mechanical, pneumatic, hydraulic and/or electrical.

The gas outflow unit can simulate human breath, in particular exhaled air. For example, the composition of the gas or gas mixture can be precisely adjusted. The individual components of the gas mixture can be individually regulated. The gas or the individual components of the gas mixture can be stored in at least one container, for example in at least one gas bottle. Individual quantities can be taken from this, for example via a valve. The container(s) can be an integral part of the torso. In this case, the torso can include an opening through which the container(s) can be filled and/or replaced as required. However, the container(s) can also be located outside the torso, for example depending on their size, whereas hoses that connect the at least one container to the at least one gas outflow opening can be an integral part of the torso. However, other designs of the gas outflow unit are also possible. The flow rate and/or flow duration and/or flow pressure and/or flow speed can be controlled and/or regulated, for example by means of at least one valve, in order to simulate human breathing processes as accurately as possible. In order to simulate human breathing, it can be advantageous if at least one gas outlet opening is located in the head at nose and/or mouth level.

However, other body exhalations such as sweat and/or other body odors should also be simulated. For this purpose, it can be advantageous if there is at least one gas outlet opening in the torso. This is advantageous, for example, to prove that a Sensor unit, for example comprising an odor sensor, which is to be tested for its functionality, cannot be influenced by gases and/or gas mixtures and/or individual components other than those it is intended to detect.

For example, it should be possible to detect alcohol and/or drugs and/or viruses in the breath.
Components, particularly in exhaled air, can be substances that indicate alcohol, such as ethanol, or cocaine, amphetamines, cannabis, tetrahydrocannabinol, morphine, methadone, ammonia, acetone, isoprene, carbon dioxide or a combination of these substances. The detection of ethanol, for example, can be used to determine whether a person is unfit to drive due to alcohol consumption. Components in exhaled air can also be volatile organic compounds, abbreviated to VOCs. VOCs include, for example, acetone, ethanol, isoprene, nonanal, decanal, α-pinene, ethyl butyrate and butanal, ethanal, propanal and n-propyl acetate. VOCs are produced in living organisms when there are protein, cell or metabolic changes. The amount of isoprene in the exhaled air and/or the room air can be used to determine whether a vehicle occupant, such as the driver, is tired, particularly in combination with the amount of carbon dioxide in the exhaled air and/or the room air. For example, characteristic protein and metabolic changes have been observed in people infected with SARS-CoV-2. VOCs excreted in exhaled air can be characteristic of a disease and thus act as a biomarker. Components in exhaled air can also be gaseous sulfur-containing compounds, also known as volatile sulfur compounds (VSCs). Examples of VSC include dimethyl sulfide, 3-methylthiophene, 3-methyl-2-buten-1-thiol, 3-methyl-1-(methylthio)-2-butene, 3-methyl-2-butenyl acetothioate, bis(3-methyl-2-butenyl) sulfide, bis(3-methyl-2-butenyl) disulfide and combinations of the above-mentioned compounds. VSC are formed, for example, when cannabis is consumed. By detecting VSC in exhaled air, it is possible to determine whether a person is unfit to drive due to cannabis consumption.

The gas mixture can contain, for example, carbon dioxide and/or water vapor and/or ethanol. But it can also contain other components. The gas mixture can also contain aerosols.

One advantage of determining substances in exhaled air is that no chemical methods, such as those that rely on a blowpipe when determining the alcohol content in exhaled air and are therefore uncomfortable, or surface contact methods, such as adsorption methods, or invasive methods are required. Exhaled air is released continuously.

It is also conceivable that the temperature of the gas and/or gas mixture can be adjusted.

If the anthropomorphic model comprises several gas outlet openings, it is also possible that, for example, a different gas and/or gas mixture flows out through each gas outlet opening.

• • Positionierung des anthropomorphen Modells relativ zu einer Sensoreinheit;
• • Ausströmung eines Gases und/oder Gasgemisches mittels der Gasströmungseinheit durch mindestens eine Gasausströmungsöffnung;
• • Erfassung des Gases und/oder Gasgemisches und/oder einzelner Bestandteile durch die Sensoreinheit.

According to a further aspect, the invention provides a method for simulating gas emissions of a driver using an anthropomorphic model, the method comprising the following steps:

• • Positioning of the anthropomorphic model relative to a sensor unit;
• • Outflow of a gas and/or gas mixture by means of the gas flow unit through at least one gas outflow opening;
• • Detection of the gas and/or gas mixture and/or individual components by the sensor unit.

The method for simulating gas emissions from a driver using an anthropomorphic model includes a step of positioning the anthropomorphic model relative to a sensor unit. This can ensure that the at least one gas emission opening is in the desired position relative to the sensor unit. The sensor unit can, for example, comprise an odor sensor. The sensor unit can, for example, be a spectroscopic measuring system, for example a laser spectroscopic measuring system that determines concentrations of the components using absorption spectroscopy or emission spectroscopy.

In a further step, a gas and/or gas mixture flows out through at least one gas outflow opening by means of the gas flow unit. It is conceivable that the composition of a gas mixture and/or the flow rate and/or the flow duration and/or the flow pressure and/or the flow rate and/or the temperature of the gas and/or gas mixture can be individually adjusted.

The method also comprises a step of detecting the gas and/or gas mixture and/or individual components by the Sensor unit. As already mentioned, the sensor unit can contain an odor sensor, for example. The odor sensor can react sensitively to ethanol, for example, in order to detect alcohol consumption through alcohol components in human breath. However, other sensors that react to other gases and/or gas mixtures and/or individual components are also conceivable.

Further developments and advantageous embodiments emerge from the subclaims, the drawings and the description of preferred embodiments.

According to one aspect, the invention provides an anthropomorphic model, wherein at least one gas outlet opening is located in the head of the anthropomorphic model. In order to simulate human breathing with the anthropomorphic model, it is advantageous if at least one gas outlet opening is located in the head, for example at the level of the nose and/or mouth of a fictitious driver. This means that a sensor unit, which can be positioned opposite the anthropomorphic model, for example at the level of a steering wheel, can detect the simulated breath as realistically as possible.

According to a further aspect, the invention provides an anthropomorphic model, wherein at least one gas outlet opening is located in the torso of the anthropomorphic model. In order to simulate human odors, such as sweat and/or other body odors, with the anthropomorphic model, it is advantageous if at least one gas outlet opening is located in the torso, for example on the front of a fictitious driver. This means that a sensor unit, which can be positioned opposite the anthropomorphic model, for example at the height of a steering wheel, comes into contact with the simulated odors as realistically as possible.

According to a further aspect, the invention provides an anthropomorphic model, wherein the anthropomorphic model comprises a temperature control unit. In order to adapt the anthropomorphic model to a human driver as realistically as possible, a temperature control unit can be advantageous. This allows, for example, the temperature at which a gas and/or gas mixture leaves a gas outlet opening to be individually controlled. For example, different gas outlet openings can have different temperatures. The temperature control unit can be an integral part of the anthropomorphic model.

According to a further aspect, the invention provides an anthropomorphic model, the anthropomorphic model comprising movable limbs.
The limbs can, for example, be attached to the torso by means of joints.

Other positions can be recreated using the limbs. For example, a standing position is possible. A position bent forwards or backwards and/or to the side is also possible. However, other positions are also conceivable.

It is conceivable that the limbs have at least one gas outlet opening.

The anthropomorphic model can include all limbs, but it can also include only individual limbs.

According to a further aspect, the invention provides an anthropomorphic model, wherein the head comprises means for displaying at least one pictorial representation of a face.

The reproduction of a face can be advantageous if a sensor unit, the functionality of which is to be tested using the anthropomorphic model, has means for facial recognition. This means that, for example, the gas and/or a gas mixture that flows out of the anthropomorphic model can be assigned to a face, i.e. to a specific person. This is useful, for example, for alcohol-sensitive immobilizers to prevent a passenger from trying to circumvent the system.

One means of visually representing a face can be, for example, a screen on which different faces can be displayed. However, it is also possible that the visual representation of a face is a type of mask, for example a printed cardboard box that can be attached to the head using fasteners.

The face can also be applied to other materials, such as plastic, styrofoam, paper or wood. However, other materials are also possible.

Other means of pictorially representing a face are also possible.

Fasteners, especially for the realization of detachable connections, are For example, Velcro, screws, clips, rubber bands or others come into consideration.

According to a further aspect, the invention provides an anthropomorphic model, wherein a gas and/or gas mixture is discharged by means of the gas discharge unit, the gas and/or gas mixture comprising carbon dioxide and/or water vapor and/or ethanol.
For example, to test a sensor unit for detecting alcohol in the breath, which may be required for alcohol-sensitive immobilizers, it may be useful to let a gas mixture containing carbon dioxide and/or water vapor and/or ethanol flow through the gas outlet unit. As already described, the gas mixture may also contain aerosols. The ethanol content can provide an indication of possible alcohol consumption by a driver.

According to a further aspect, the invention provides an anthropomorphic model, wherein a gas and/or gas mixture is emitted by means of the gas emission unit, the gas and/or gas mixture comprising tetrahydrocannabinol. For example, in order to test a sensor unit for detecting drugs based on breath and/or other body odors, it may be useful to let a gas mixture comprising tetrahydrocannabinol flow through the gas emission unit. As already described, the gas mixture may also contain aerosols. The tetrahydrocannabinol content may indicate possible drug consumption by a driver. However, other components of a gas mixture may also indicate possible drug consumption.

According to a further aspect, the invention provides an anthropomorphic model, wherein the gas outflow unit has means to control and/or regulate the flow rate and/or the flow duration and/or the flow pressure and/or the flow rate.
In order to simulate human breath and/or other human exhalations as realistically as possible, it can be advantageous to control the flow rate and/or flow duration and/or flow pressure and/or flow speed. This can be done, for example, via at least one valve. Individual parameters do not have to be constant, but can also change over time, for example.

• 1 eine schematische Seitenansicht eines Ausführungsbeispiels eines anthropomorphen Modells,
• 2 eine schematische Seitenansicht eines weiteren Ausführungsbeispiels eines anthropomorphen Modells,
• 3 ein Flussdiagramm eines erfindungsgemäßen Verfahrens.

The invention is explained by way of example using the following embodiments. They show:

• 1 a schematic side view of an embodiment of an anthropomorphic model,
• 2 a schematic side view of another embodiment of an anthropomorphic model,
• 3 a flow chart of a method according to the invention.

In the figures, identical reference symbols refer to identical or functionally similar objects. In order to avoid repetition, only the relevant objects are identified by reference symbols in the figures.

In the 1 The schematic side view of an embodiment of an anthropomorphic model 100 according to the invention shown comprises a head 101 and a torso 102. 1 shows an example of a gas outlet opening 103, which is attached to the head 101 in the area of a fictitious nose. According to 1 for example a gas mixture 104. 1 also shows a sensor unit 105, which can detect, for example, the gas mixture 104 and/or individual components.

In the 2 The schematic side view of an embodiment of an anthropomorphic model 100 according to the invention shown in FIG. 1 comprises, in addition to a head 101 and a torso 102, also limbs 107. The limbs 107 comprise, according to 2 at least one upper arm, one forearm, one thigh, one lower leg and one foot.
2 shows, by way of example, a gas outlet opening 103 on the head 101, a gas outlet opening 103 on the torso 102 and a gas outlet opening 103 on the limbs 107, wherein a gas mixture 104 flows through the gas outlet opening 103 on the head 101 and the gas outlet opening 103 on the limbs 107 and a gas 106 flows through the gas outlet opening 103 on the torso 102. 2 also shows a sensor unit 105, which can detect, for example, the gas 106 and/or gas mixture 104 and/or individual components.

This in 3 The flow chart of a method according to the invention shown comprises a step 200 of positioning the anthropomorphic model 100 relative to a sensor unit 105. In addition, the 3 The method shown comprises a step 201 of the outflow of a gas 106 and/or gas mixture 104 by means of the gas flow unit through at least one gas outflow opening 103 and a step 202 of the detection of the gas 106 and/or gas mixture 104 and/or individual components by the sensor unit 105.

Reference symbol

100

Anthropomorphic model

101

Head

102

torso

103

Gas outlet opening

104

Gas mixture

105

Sensor unit

106

gas

107

Limbs

200 - 202

Process steps

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA accepts no liability for any errors or omissions.

Cited patent literature

• EP2019/2144 [0003]

Claims (10)

Anthropomorphic model (100) for simulating gas emissions of a driver, the anthropomorphic model (100) comprising: • a head (101); • a torso (102); • at least one gas emission unit, wherein the gas emission unit is designed to simulate human breath and/or other body emissions, wherein the gas emission unit comprises at least one gas emission opening (103). Anthropomorphic model (100) according to Claim 1 , wherein at least one gas outlet opening (103) is located in the head (101) of the anthropomorphic model. Anthropomorphic model (100) according to one of the preceding claims, wherein at least one gas outlet opening (103) is located in the torso (102) of the anthropomorphic model (100). Anthropomorphic model (100) according to one of the preceding claims, wherein the anthropomorphic model (100) comprises a temperature control unit. Anthropomorphic model (100) according to one of the preceding claims, wherein the anthropomorphic model comprises movable limbs (107). Anthropomorphic model (100) according to one of the preceding claims, wherein the head (101) comprises means for displaying at least one pictorial representation of a face. Anthropomorphic model (100) according to one of the preceding claims, wherein a gas (106) and/or gas mixture (104) is discharged by means of the gas discharge unit, the gas (106) and/or gas mixture (104) comprising carbon dioxide and/or water vapor and/or ethanol. Anthropomorphic model (100) according to one of the preceding claims, wherein a gas (106) and/or gas mixture (104) is emitted by means of the gas emission unit, the gas (106) and/or gas mixture (104) comprising tetrahydrocannabinol. Anthropomorphic model (100) according to one of the preceding claims, wherein the gas outflow unit has means to control and/or regulate the flow rate and/or the flow duration and/or the flow pressure and/or the flow rate. Method for simulating gas outflow of a driver using an anthropomorphic model (100) according to one of the preceding claims, the method comprising the following steps: • Positioning the anthropomorphic model (100) relative to a sensor unit (105); • Outflow of a gas (106) and/or gas mixture (104) by means of the gas flow unit through at least one gas outflow opening (103); • Detection of the gas (106) and/or gas mixture (104) and/or individual components by the sensor unit (105).

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