J. Dubard, J.-R. Filtz, V. Cassagne, P. Legrain
SOLAR METROLOGY: PHOTOVOLTAIC MODULE PERFORMANCE MEASUREMENTS

The performance of a photovoltaic module is mainly defined by the maximum power Pmax, which is measured under standard conditions (1000 W/m², AM 1.5, 25°C) using a sunlight (natural or simulated) and a calibrated reference device. This reference photovoltaic device, placed in the same lighting conditions than the module under test, allows the measurement of the sunlight levels through the monitoring of the maximum power of these devices. As a key metric for photovoltaics economy, the measurement of P_max must be a subject of a strong attention. This paper describes the metrology applied and the typical levels of uncertainties achievable by National Laboratories as well as in the Industry.

Moo-Young Seok, Dong-Hyun Lee, Jung-A Lee, Yong-Jae Kim, Yun-Hee Lee, Un Bong Baek, Seung Hoon Nahm, Jae-il Jang
INFLUENCES OF HYDROGEN ON THE MECHANICAL BEHAVIOR OF WELD HEAT-AFFECTED ZONE IN API STEEL PIPELINE

To prepare the up-coming era of so-called ‘hydrogen economy,’ many researches on the related infrastructures are actively conducted around the world. One of the important issues on the topic is hydrogen transmission. Recently, the use of existing natural gas pipeline is often considered as an cost-effective way of hydrogen transmission. However, while much researches have been performed on the possible hydrogen effects on the mechanical performance of pipeline steels, few study has been reported for the influence of hydrogen on the mechanical behavior of their weld heat-affected zone (HAZ), that is well known to be the weakest in the pipeline. In the present study, various HAZs are simulated, and the hydrogen effects on their mechanical behavior were systematically investigated through indentation, tensile tests, and impact tests.

A. Yun-Hee Lee, B. Yongil Kim, C. Jongseo Park, D. Unbong Baek, E. Kwon Sang Ryu
DEVELOPMENT OF A REFERENCE MATERIAL FOR HYDROGEN CONTENTS MEASUREMENT

By heating a metal sample exposed to hydrogen environment until its melting point, whole hydrogen can be released and its content is quantitatively measured with a thermal conductivity detector (TCD). Reference materials with already-known hydrogen contents are needed to calibrate the detector. In this study, we proposed a new concept for making the reference material; the targeted hydrogen content can be obtained by controlling mixing amount of a hydride with its balancing weight. The hydrogen contents can be roughly calculated by considering the chemical stoichiometry of the hydride. A linear proportional relationship was identified between the calculated hydrogen contents and the empirically measured values from the detector. However, both hydrogen contents did not coincide with each other numerically. This phenomenon was discussed from several factors such as partial hydrogenation and air-bone contaminants in the hydride, inconsistent calibration procedure, impurity involved in the measurement, etc.

S. Seitz, P. Spitzer, F. Durbiano, H. Jensen
ELECTROLYTIC CONDUCTIVITY AS A QUALITY INDICATOR FOR BIOETHANOL

This work introduces the European Metrology Research Project on the SI traceability of electrolytic conductivity measurements in bioethanol. As a first step to this aim secondary conductivity measurements have been performed to characterise reproducibility, stability, measurement uncertainty and the significance of the measurement results. The standard measurement uncertainty is in the order of 0.3 %. Two samples from different sources show significantly different conductivity values. The results indicate that conductivity is an appropriate quality indicator for bioethanol.

H. Wolf, S. Heinsch
DENSITY MEASUREMENTS OF LIQUID FUELS TO DETERMINE TEMPERATURE CONVERSION FACTORS FOR LEGAL METROLOGY

Worldwide there are great efforts to reduce the CO2 emission into the atmosphere by using fuels made from biomass. These biofuels are normally blended with fossil fuels.
For legal metrology the thermal expansion coefficient, the so-called temperature conversion factor, is of great importance to guarantee correct measurements of the fuel volume. Thus, the density of fossil fuels blended with biofuels was measured at the Physikalisch-Technische Bundesanstalt (PTB). Investigations were performed on mixtures of fossil petrol with ethanol and of fossil Diesel with biodiesel.
The volume concentration of the biofuels component varied between 0 % and 100 % in order to have data available for all possible mixtures. The data were measured in a temperature range between -10 °C and +50 °C.