NO133163B - - Google Patents

Description

The invention relates to a small test tube for quantitative detection of the alcohol content, of respiratory

air on the basis of bichromate-sulphuric acid on silica gel.

It is already known to detect respiratory alcohol by reducing chromium (VI) compounds to chromium (III) compounds in a strongly sulfuric acid medium.

Furthermore, it is known as non-porous elements

to use glass beads, powdered glass or ceramic particles. It has also already been described to use the particles that are used as non-porous bases in the form of small bodies of uniform shape with a roughened surface. Furthermore, as an absorbent to be applied, it has become known, among other things, clay quartz flour, bauxite and bleached earth. The particle size of the non-porous elements discussed so far ranges between s.05 and 0.35 mm.

Thermocolor dye has been used as an indicator to measure the volume of the respiratory air that is blown through the layers that demonstrate this in order to determine its alcohol content. In the unfilled part, a solution of dithizone has been melted into a destructible ampoule. Furthermore, it is known that the volume measurement required for an alcohol determination can take place at the constant moisture content of the respiratory air at 37°C using a water-detecting reaction chemical. In this method, a layer of uniform fine-grained blue gel is coupled in front of the alcohol-detecting reaction mass. The absorption of the alcohol that takes place in this upstream layer must, when assessing the alcohol instructions, be taken into account in advance.

In addition, small test tubes are also known where the reagent-equipped layer is placed either on the inner walls of the small tubes or on the mantle of the inserted filling body in any case. The filling body must be held in position by point-shaped indentation.

All the known methods have the disadvantage that, due to the large internal surface and small cone size of the silica gel used, as well as the high amount of sulfuric acid applied to this gel, which is necessary in any case, amounts to well over 10% by weight, referred to the chemical, there is no satisfactory separation of respiratory moisture and respiratory alcohol. In this way, it is not possible to have a quantitative, longitudinal colorometric determination of the alcohol content in the breathing air in an area below 1.5 o/oo.

The amount of alcohol, which is very small in relation to the humidity, dissolves completely, with the help of the silica gel-sulphuric acid mixture absorbing water so that, depending on the alcohol content of the breathing air, zones of approximately the same length only differ in color. The necessary assessment of the sample by means of color comparison is, in contrast to quantitative length-colorometric assessment, fraught with errors. With different lighting conditions, the assessment of the color comparison is often impossible.

Further, against a quantitative determination is the order of magnitude of the known elements of non-porous structure, grains of 0.05 to 0.35 mm appear to be on average too small, to be able to find use in small test tubes with quantitative alcohol indication.

Cleaning up the surface, which is also mentioned, turns out to be an uneconomical precaution, while glazed materials cannot be used with the desired result.

Furthermore, the high amount of chromate necessary due to the large inner surface of the silica gel makes a longitudinal colorometric assessment at different alcohol concentrations difficult. The reaction layers used in this method prevent the volume measurement required for a quantitative alcohol determination by means of a connected water-attracting layer. The attempt to make the volume indication visible with a pre-connected blue gel layer leads to an additional reduction in the respiratory alcohol concentration, as no separation of water-alcohol takes place in the blue gel layer.

Volume measurement using thermocolor dye has the disadvantage of color comparison as well as the effect of this dye, which from 43 to 47°C is reversibly color-changeable with the help of the external temperature. This method also has the shortcoming that for alcohol concentrations below 1.5 o/oo, an additional detection with the aid of dithizone must be added, which does not, however, enable any longitudinal colorometric assessment of the alcohol content.

In any embodiment of the test tube equipped with a filler, there is no guarantee that the total sample medium flowing through the formed gap comes into contact with the reagent, which is an unconditional prerequisite for a quantitative determination.

The passage of the gas to be examined between two concentric cylinder surfaces, of which either the inner or outer is equipped with the detecting layer, proves to be unfortunate because a wide gap resists with too little resistance to the sample medium and thus has an immediate spread in the overall rooms available to the media. If, on the other hand, a narrow gap is chosen, then the flow rate of the gas to be examined is correspondingly high and the residence time in the small test tube is considerably reduced and a complete reaction cannot take place. For the design of a zone which first enables the immediate quantitative assessment, the uniform flow of the sample medium required on all sides can also hardly be achieved, as even the smallest edge formation of the filling body opposite the sample tube is sufficient to not fulfill this condition.

In each of the aforementioned cases, it is consequently not possible to make a quantitative assessment of the instruction.

The invention is based on the task of providing a small test tube for quantitative alcohol detection, especially in respiratory air.

The test tube must enable a good assessment in a length-colometric way.

The invention therefore relates to small test tubes for the quantitative detection of the alcohol content in the respiratory air using bichromate-sulphuric acid which, together with porous materials, is applied to non-porous materials, as a transparent small tube is filled with non-porous materials such as glass particles, quartz particles or plastic granules , for example granules of polytetrafluoroethylene coated with inorganic porous materials impregnated with potassium-bichromate-sulfuric acid such as silica gel, aluminum oxide, ceramic masses or substances, which are used for the production of molecular sieves, e.g. zeolites, the tubes being characterized by the weight ratio between porous material and potassium bicarbonate and sulfuric acid being within the limits 10 : 0.1 to 0.3 : 3 to 11 and the weight ratio between porous materials and non-porous materials being within the limits 10 : 20 to 65 and that the small tube in the area of the detecting part for determining the amount of alcohol contained in the respiratory air in a longitudinal colorimetric manner is equipped with a scale.

The determination of the respiratory volume required for the assessment can be carried out with the help of a connected water-detecting layer or a measuring bag can be connected in a manner known per se.

In addition to glass particles, quartz particles, plastic granules, e.g. granules based on polytetrafluoroethylene, or similar chromium-sulphuric acid-resistant particles of inorganic or organic origin.

Porous materials include, in addition to silica gel dust, aluminum oxide, ceramic masses or substances, which are used for the production of molecular sieves such as e.g. zeolites, as well as corresponding porous materials which are resistant to chromosulfuric acid. The dust used each time must have a grain size below 0.1 mm.

Furthermore, it was found that the non-porous materials to be used can be of arbitrary structure, but must have an average size between 0.25 and 1.0 mm in diameter.

In addition, it was determined that the test tube's filling must have a length of 20 to 40 mm so that, depending on the average size of the non-porous particles, the filling layer stands against the respiration flow, which is to be examined with an air resistance between 40 and 80 mm water column measured at a flow rate - heat of 1 liter per minute for achieving a high detection

and reading accuracy.

It was further determined that the weight ratio between porous materials such as silica gel, aluminum oxide or zeolite resp. similar dust and potassium bichromate, and sulfuric acid must move within the limits of 10 : 0.1 to 0.3 : 3 to 11, to obtain the desired effect.

The test tube created in this way has the following advantageous properties: a) The continuous reaction of the alcohol with chromic sulfuric acid only at the outer surface of the reagent gives a color zone that is proportional to the alcohol content in the respiratory air and continuously develops.

b) The use of a small precisely determined sulfuric ■ acid whose quantity in the chemical is below 10% by weight, and the

small surface area of the carrier material reduces water absorption to such an extent that a subsequent water-sensitive layer enables an accurate volume measurement. The amount of sulfuric acid is chosen so that with a constant amount of chemical, water enters the downstream water-sensitive layer after exactly 1 liter of breathing air and the investigation is thus finished. A further advantage of the small amount of sulfuric acid is that, in the event of a break in the test tube, there is no more risk of corrosion, in contrast to the test tube with a sulfuric acid application of more than 10 wt. in chemistry.

e) The thus obtained extension of the color zone front at low alcohol content as well as the low water absorption

ensures a much more favorable separation effect than the previously proposed chemicals between alcohol and respiratory moisture.

The invention shall be explained in more detail by means of working examples. Example 1.

500 g of sulfuric acid-cleaned glass particles of grain size 0.25 to 0.4 mm are impregnated in a rotating container evenly with 100 ml of water glass. After the continuous application of 150 g of silica gel dust with a grain size of less than 0.1 mm, the thus produced mass is dried at 180°C. The porous raw product is then crushed, the desired grain size is sieved out and dried again before use.

100 g of the carrier material thus prepared with a grain size of 0.6 to 1 mm is impregnated with a solution of 0.3 g of potassium bichromate in 6 ml of 90% sulfuric acid and to improve the flowability of the reagent thus formed, 3 g of silica gel dust is added under 0.1 mm grain size.

Example 2.

500 g of sulfuric acid-cleaned glass particles with a grain size of 0.25 to 0.4 mm are impregnated in a rotating container evenly with 140 ml of water glass. After the continuous application of 75 g of zeolite dust with a grain size below 0.1 mm, the thus formed mass is dried at 180°C. The porous product is then crushed, the desired grain size is sieved out and dried again before use. 100 g of the above-mentioned material of grain size 0.6 to 1 mm is impregnated with a solution of 0.3 g of potassium bichromate in 6 ml of 90% sulfuric acid. Finally, 3 g of finely divided zeolite dust is also applied to the reagent.

Example 3.

500 g polytetrafluoroethylene granules of grain size 0.4 to 0.75 mm are evenly impregnated with 125 ml glass of water. After a continuous application of 100 g of silica gel dust with a grain size of less than 0.1 mm, the mass is dried at 180°C.

The further processing takes place according to the example

1, in that the material prepared for the application of the bichromate-sulfuric acid reagent has a grain size from 0.8

to 1.2 mm.

Example 4.

500 g of quartz particles cleaned with sulfuric acid of grain size 0.75 to 1 mm are evenly impregnated with 100 ml of water glass. After the continuous application of 150 g of aluminum oxide dust of a grain size below 0.1 mm, the mass is dried at 180°C. The porous product is then crushed, the desired grain size is selected and subjected to repeated drying.

100 g of the above-mentioned material of grain size 1.0 to 1.5 mm is impregnated with a solution of 0.2 g of potassium bichromate in 4 ml of 90% sulfuric acid. Then, 2 g of aluminum oxide dust is also applied to improve the paddling ability.

The material prepared according to examples 1 to 4 is filled into the small tubes equipped with an adjusted scale, with a grain size of the expected porous material prepared for the application of the bichromate-sulphuric acid reagent corresponding to

from 0.6 to 1.0 mm of a fill height of approx. 20 mm from 0.8 to 1.2 mm of a filling height of approx. 30 mm and from 1.0 to 1.5 mm of a filling height of approx. 40 mm.

It is possible, for example, to place a graduation for 0.1), 0.8, 1.2, 1.6 and 2.0 per thousand and read with a guaranteed accuracy of ±0.2 per thousand.

Claims (4)

1. The invention relates to small test tubes for quantitative detection of the alcohol content in the respiratory air using bichromate-sulphuric acid which, together with porous materials, is applied to non-porous materials, in that a small transparent tube is filled with non-porous materials such as glass particles, quartz particles or plastic granules, for example granules of polytetrafluoroethylene coated with inorganic porous materials impregnated with potassium-bichromate-sulfuric acid such as silica gel, aluminum oxide, ceramic masses or substances used for the production of molecular sieves, e.g. zeolites, characterized in that the weight ratio between porous material and potassium bichromate and sulfuric acid lies within the limits 10 : 0.1 to 0.3 : 3 to 11 and the weight ratio between porous materials and non-porous materials lies within the limits 10 : 20 to 65" and that the small tube in the area of the detecting part for determining the amount of alcohol contained in the respiratory air in a longitudinal colorimetric manner is equipped with a scale. 2. Test tube according to claim 1, characterized in that the introduced porous material has a grain size below 0.1 mm. 3. Test tube according to claim 1, characterized in that the non-porous material used has an arbitrary structure and an average grain size between "0.25 and 1 mm. 4. Test tube according to claims 1 to 3, characterized in that the filling has a length of 20 to 40 mm, as the air resistance measured at a flow rate of 1 litre/minute should be between 40 and 80 mm water column.