Qualitative behaviour of L1 and L2 standard deviation in insulations measurements according to standard UNE EN ISO 140-4

Knowledge of the uncertainty of measurement of testing results is important when results have to be compared with limits and specifications. In the measurement of sound insulation following standards UNE EN ISO 140-4 the uncertainty of the final magnitude is mainly associated to the average sound pressure levels L1 and L2 measured. A parameter that allows us to quantify the spatial variation of the sound pressure level is the standard deviation of the pressure levels measured at different points of the room. In this work, for a wide number of measurements following standards UNE EN ISO 140-4 we analyzed qualitatively the behaviour of the standard deviation for L1 and L2. The study of sound fields in enclosed spaces is very difficult. There are a wide variety of rooms with different sound fields depending on factors as volume, geometry and materials. In general, we observe that the L1 and L2 standard deviations contain peaks and dips independent on characteristics of the rooms at single frequencies that could correspond to critical frequencies of walls, floors and windows or even to temporal alterations of the sound field. Also, in most measurements according to UNE EN ISO 140-4 a large similitude between L1 and L2 standard deviation is found. We believe that such result points to a coupled system between source and receiving rooms, mainly at low frequencies the shape of the L1 and L2 standard deviations is comparable to the velocity level standard deviation on a wall

Efectos de la vibración de la pared sobre la desviación estándar de L2 en ensayos UNE EN ISO 140-4 y 140-5

En los ensayos de aislamiento acústico según normas UNE EN ISO 140-4 y 140-5 el valor de L2 es un promedio espacio-temporal de los niveles de presión sonora medidos en diferentes posiciones de la sala receptora. La desviación estándar de estos valores se puede considerar como una medida de la uniformidad del campo sonoro en el recinto. Se analiza este parámetro en función de la frecuencia y se propone un cálculo teórico del mismo como una incertidumbre combinada de la desviación estándar derivada de modelos teóricos centrados en la geometría del recinto y la desviación estándar asociada a la vibración de la pared separadora

Procedimiento para la medición y verificación de la directividad y la cobertura de una fuente sobre un elemento de fachada de acuerdo a la norma ISO 140-5

El apartado <4.2 Altavoz> de la Norma Internacional UNE-EN ISO 140-5 [1] especifica que la directividad del altavoz usado en el ensayo debe asegurar en todas las bandas de frecuencias de interés, unas diferencias de nivel locales inferiores a 5dB (o a 10 dB para fachadas de dimensiones mayores a 5m), medidas en campo libre, sobre una superficie del mismo tamaño y orientación que la pared o elemento a ensayar. Este requisito debe verificarse en unas bandas de frecuencia de interés que sean como mínimo los tercios de octava desde 100Hz hasta 3150Hz, y preferiblemente desde 50Hz hasta 5kHz. Desde hace unos años, en el Laboratorio de sonido de la EUIT de Telecomunicación de la Universidad Politécnica de Madrid, los autores han implementado un método en el que, a partir de las medidas de directividad en cámara anecoica de la fuente sonora a ensayar, se calcula el campo sonoro directo sobre una superficie ficticia que representa un elemento de fachada en la misma disposición que se indica en la norma ICO 140-5 y con unas dimensiones según se requieran en el procedimiento. También se estima la dimensión horizontal máxima ΔXmax de una fachada rectangular en relación de aspecto fija que permite verificar la norma con los criterios de 5dB y 10dB de diferencias máximas de niveles directos en dicha fachada. En esta ponencia se detalla el procedimiento anterior. ABSTRACT. The Section "4.2 loudspeaker" of the UNE-EN ISO 140-5 International Standard: "Field measurements of airborne sound insulation of façade elements and façades", specifies that the directivity of the loudspeaker used in the test must ensure in all frequency bands of interest, local level differences less than 5dB (or 10dB for façade dimensions greater than 5m), measured in free field over an area of the same size and orientation as the wall or element to be tested. This requirement must be verified in the frequency bands of interest which are, at least, the third octave bands from 100Hz to 3150Hz, preferably from 50Hz to 5kHz. In recent years, in the Laboratory of Sound of the EUIT Telecomunicación (Universidad Politécnica de Madrid), the authors have implemented a method that, from directivity measurements of loudspeakers performed in the anechoic room, the direct sound field on a surface in the same layout as indicated in the ISO standard is calculated. It is also estimated the maximum horizontal dimension Δxmax of a rectangular façade for each aspect ratio which verify the standard criteria of either 5dB or 10dB for the maximum differences of direct levels in the façade. This paper details the procedure above introduced.

Environmental risk assessment in open pit blasting operations: compliance with ISO 31010:2010

All activities of an organization involve risks that should be managed. The risk management process aids decision making by taking account of uncertainty and the possibility of future events or circumstances (intended or unintended) and their effects on agreed objectives. With that idea, new ISO Standard has been drawn up. ISO 31010 has been recently issued which provides a structured process that identifies how objectives may be affected, and analyses the risk in term of consequences and their probabilities before deciding on whether further treatment is required. In this lecture, that ISO Standard has been adapted to Open Pit Blasting Operations, focusing in Environmental effects which can be managed properly. Technique used is Fault Tree Analysis (FTA), which is applied in all possible scenarios, providing to Blasting Professionals the tools to identify, analyze and manage environmental effects in blasting operations. Also this lecture can help to minimize each effect, studying each case. This paper also can be useful to Project Managers and Occupational Health and Safety Departments (OH&S) because blasting operations can be evaluated and compared one to each other to determine the risks that should be managed in different case studies. The environmental effects studied are: ground vibrations, flyrock and air overpressure (airblast). Sometimes, blasting operations are carried out near populated areas where environmental effects may impose several limitations on the use of explosives. In those cases, where these factors approach certain limits, National Standards and Regulations have to be applied.

Influence of loudspeaker directivity and measurement geometry on direct acoustic levels over façades for acoustic insulation tests with the International Standard ISO 140-5

The International Standard ISO 140-5 on field measurements of airborne sound insulation of façades establishes that the directivity of the measurement loudspeaker should be such that the variation in the local direct sound pressure level (ΔSPL) on the sample is ΔSPL < 5 dB (or ΔSPL < 10 dB for large façades). This condition is usually not very easy to accomplish nor is it easy to verify whether the loudspeaker produces such a uniform level. Direct sound pressure levels on the ISO standard façade essentially depend on the distance and directivity of the loudspeaker used. This paper presents a comprehensive analysis of the test geometry for measuring sound insulation and explains how the loudspeaker directivity, combined with distance, affects the acoustic level distribution on the façade. The first sections of the paper are focused on analysing the measurement geometry and its influence on the direct acoustic level variations on the façade. The most favourable and least favourable positions to minimise these direct acoustic level differences are found, and the angles covered by the façade in the reference system of the loudspeaker are also determined. Then, the maximum dimensions of the façade that meet the conditions of the ISO 140-5 standard are obtained for the ideal omnidirectional sound source and the piston radiating in an infinite baffle, which is chosen as the typical radiation pattern for loudspeakers. Finally, a complete study of the behaviour of different loudspeaker radiation models (such as those usually utilised in the ISO 140-5 measurements) is performed, comparing their radiation maps on the façade for searching their maximum dimensions and the most appropriate radiation configurations.