Method and apparatus for determining the permeation rate of barrier materials

The invention claimed is: 1. Method for determining the permeation rate of barrier materials, wherein in a measuring chamber ( 8 . 7 ) which has at least two shut-off elements ( 8 . 1 ; 8 . 2 ) for opening and closing, a concentration of at least one permeate is determined which, present as a test gas with a constant concentration in a test gas chamber ( 8 . 3 ), is permeated into the measuring chamber ( 8 . 7 ) through a barrier element ( 8 . 5 ) which is arranged between the test gas chamber ( 8 . 3 ) and the measuring chamber ( 8 . 7 ) and which has a known permeable surface (A); wherein in a process step (i), the measuring chamber ( 8 . 7 ) is purged with a constant permeate-free purge gas volume flow ({dot over (V)}) by opening the shut-off elements ( 8 . 1 ; 8 . 2 ) once a predefinable upper switchover concentration (cvA) has been reached in a first measurement variant or once a predefinable enriching time (tvA) has been reached in the second measuring variant; wherein the permeate concentration (c) in the open measuring chamber ( 8 . 7 ) drops as a result of the purging; and the time course of this permeate concentration (c) is either determined up to the reaching of a predefinable lower switchover concentration (cvS) in the first measurement variant, with a purge time (tS) being determined in this respect, or up to the reaching of a predefinable purge time (tvS) in the second measurement variant; and in a process step (ii), on reaching the predefinable lower switchover concentration (cvS) in the first measurement variant or on reaching the predefinable purge time (tvS) in the second measurement variant, the measuring chamber ( 8 . 7 ) is closed by closing the shut-off elements ( 8 . 1 ; 8 . 2 ), with the permeate concentration (c) increasing in the closed measuring chamber ( 8 . 7 ) as a result of the permeation, with an enriching time (tA) up to the reaching of the predefinable upper switchover concentration (cvA) being determined in the first measurement variant; and subsequently using the enriching time (tA) and using the purge time (tS) determined in process step (i) using the first measurement variant and using the course of the permeate concentration (c) determined during the purge time (tS), or the course of the permeate concentration (c) during the predefinable purge time (tvS) being determined in the process step (i) of the second measurement variant, the predefinable purge time (tvS) and the predefinable enriching time (tvA), the permeation rate (P) of the barrier element ( 8 . 5 ) is calculated using the equation P = ∫ ( c ⁡ ( t ) · V . ) ⁢ ⅆ t · M · p R · T · t total · A where t total is the sum of the purge time (tS) and of the enriching time (tA) for the first measurement variant and is the sum of the predefinable purge time (tvS) and of the predefinable enriching time (tvA) for the second measurement variant; M is the molar mass of the permeate; p is the maintained pressure, R is the general gas constant; and T is the temperature maintained during process steps (i) and (ii). 2. A method in accordance with claim 1 , characterized in that the method is carried out starting with process step (i) or with process step (ii). 3. A method in accordance with claim 1 , characterized in that the permeation rate (P) is respectively determined from at least one measurement cycle respectively comprising at least one process step (i) and at least one process step (ii). 4. A method in accordance with claim 3 , characterized in that in the second measurement variant, an upper switchover concentration value (cA) is adopted at the end of the predefinable enriching time (tvA) and a lower switchover concentration value (cS) is adopted at the end of the predefinable purge time (tvS). 5. A method in accordance with claim 4 , characterized in that the measurement cycle is repeated until the lower switchover concentration (cS) coincides with the lower switchover concentration value of the measurement cycle directly before it in time or differs from it by a maximum of twice the measurement uncertainty and simultaneously the difference between the upper switchover concentration value (cA) and the lower switchover concentration value (cS) coincides with that of the measurement cycle directly before it in time or differs from it by a maximum of twice the measurement uncertainty. 6. A method in accordance with claim 1 , characterized in that the measurement cycle is repeated in the first measurement variant until the total cycle time resulting from the sum of the enriching time (tA) and the purge time (tS) coincides with that of the measurement cycle directly before it in time or differs from it by a maximum of twice the measurement uncertainty. 7. A method in accordance with claim 1 , characterized in that the measurement cycle is repeated until the respective determined permeation rate of a measurement cycle coincides with the permeation rate of at least one preceding measurement cycle or differs from it by a maximum of 20%. 8. A method in accordance with claim 1 , characterized in that the measuring chamber ( 8 . 7 ) is prepurged with the permeate-free purge gas volume flow({dot over (V)}) at least once prior to carrying out the first measurement cycle by opening the shut-off elements ( 8 . 1 ; 8 . 2 ) and the measuring chamber ( 8 . 7 ) is subsequently closed again by closing the shut-off elements ( 8 . 1 ; 8 . 2 ) and remains closed sufficiently long until a state of equilibrium is reached in the measuring chamber ( 8 . 7 ). 9. A method in accordance with claim 1 , characterized in that a non-invasive, optical and/or capacitive measuring method ( 8 . 6 ) is used for determining the permeate concentration and/or the change in the permeate concentration in the gas phase of the measuring chamber ( 8 . 7 ). 10. A method in accordance with claim 9 . characterized in that a UV, VIS, NIR, MIR, quantum cascade laser spectrometer, a cavity ring-down spectrometer or a terahertz spectrometer is used as the measuring method. 11. A method in accordance with claim 9 , characterized in that a laser-based measuring process, is used which uses at least one laser beam having an emission wavelength coordinated to the permeate(s) to be detected. 12. A method in accordance with claim 1 , characterized in that condensable gases and vapors, preferably water vapor, is/are used as the test gas.