kSIST FprEN ISO 10140-3:2021

SLOVENSKI STANDARD
oSIST prEN ISO 10140-3:2020
01-september-2020

Akustika - Laboratorijsko merjenje zvočne izolirnosti gradbenih elementov - 3. del:

Acoustics - Laboratory measurement of sound insulation of building elements - Part 3:

Akustik - Messung der Schalldämmung von Bauteilen im Prüfstand - Teil 3: Messung der

construction - Partie 3: Mesurage de l'isolation au bruit de choc (ISO/DIS 10140-3:2020)

2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

Acoustique — Mesurage en laboratoire de l'isolation acoustique des éléments de construction —

All rights reserved. Unless otherwise specified, or required in the context of its implementation, no part of this publication may

be reproduced or utilized otherwise in any form or by any means, electronic or mechanical, including photocopying, or posting

on the internet or an intranet, without prior written permission. Permission can be requested from either ISO at the address

Foreword ........................................................................................................................................................................................................................................iv

Introduction ..................................................................................................................................................................................................................................v

1 Scope ................................................................................................................................................................................................................................. 1

2 Normative references ...................................................................................................................................................................................... 1

3 Terms and definitions ..................................................................................................................................................................................... 2

4 Facilities and equipment .............................................................................................................................................................................. 2

5 Test procedure and evaluation .............................................................................................................................................................. 3

5.1 General procedure ............................................................................................................................................................................... 3

5.2 Generation of sound field ............................................................................................................................................................... 3

5.3 Data processing ...................................................................................................................................................................................... 4

5.4 Correction of airborne sound transmission ................................................................................................................... 4

5.5 Expression of results .......................................................................................................................................................................... 5

6 Test arrangement ................................................................................................................................................................................................. 6

6.1 General ........................................................................................................................................................................................................... 6

6.2 Types of installation ........................................................................................................................................................................... 6

6.2.1 Floor element ...................................................................................................................................................................... 6

6.2.2 Floor covering .................................................................................................................................................................... 6

7 Limits of performance .................................................................................................................................................................................... 6

8 Measurement uncertainty .......................................................................................................................................................................... 6

9 Test report ................................................................................................................................................................................................................... 6

Annex A (informative) Measurement using heavy and soft impact sources ...............................................................8

Annex B (informative) Form for the expression of results .........................................................................................................12

Bibliography .............................................................................................................................................................................................................................14

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different types of ISO documents should be noted. This document was drafted in accordance with the

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This document was prepared by Technical Committee ISO/TC 43, Acoustics, Subcommittee SC 2, Building

This second edition cancels and replaces the first edition (ISO 10140-3:2010) and the Amendment

Any feedback or questions on this document should be directed to the user’s national standards body. A

ISO 10140 (all parts) concerns laboratory measurement of the sound insulation of building elements

ISO 10140-1 specifies the application rules for specific elements and products, including specific

requirements for preparation, mounting, operating and test conditions. ISO 10140-2 and this part of

ISO 10140 contain the general procedures for airborne and impact sound insulation measurements,

respectively, and refer to ISO 10140-4 and ISO 10140-5 where appropriate. For elements and products

without a specific application rule described in ISO 10140-1, it is possible to apply ISO 10140-2 and

this part of ISO 10140. ISO 10140-4 contains basic measurement techniques and processes. ISO 10140-5

contains requirements for test facilities and equipment. For the structure of ISO 10140 (all parts), see

ISO 10140 (all parts) was created to improve the layout for laboratory measurements, ensure

consistency and simplify future changes and additions regarding mounting conditions of test elements

in laboratory and field measurements. It is intended for ISO 10140 (all parts) to present a well-written

ISO 10140-1 It indicates the appropriate test Appropriate references to ISO 10140-2 and ISO 10140-3 and

procedure for elements and product-related, specific and additional instructions on:

ISO 10140-2 It gives a complete procedure for – Definitions of main quantities measured

ISO 10140-3 It gives a complete procedure for – Definitions of main quantities measured

This part of ISO 10140 specifies laboratory methods for measuring the impact sound insulation of floor

The test results can be used to compare the sound insulation properties of building elements, classify

elements according to their sound insulation capabilities, help design building products which require

certain acoustic properties and estimate the in situ performance in complete buildings.

The measurements are performed in laboratory test facilities in which sound transmission via flanking

paths is suppressed. The results of measurements made in accordance with this part of ISO 10140

are not applicable directly to the field situation without accounting for other factors affecting sound

A test method is specified that uses the standard tapping machine (see ISO 10140-5:2020, Annex E) to

simulate impact sources like human footsteps when a person is wearing shoes. This part of ISO 10140 is

applicable to all types of floors (whether heavyweight or lightweight) with all types of floor coverings.

NOTE When the aim of impact sound insulation measurements is to have a strong correlation between a

“real” impact source (e.g. a person walking or children jumping) and an artificial impact source (e.g. a tapping

machine), it is intended that both sources apply the same input force spectrum to ensure the correct ranking of

floors and floor coverings for the “real” and the artificial source, and it is intended that the impedance spectra of

the sources be the same. If the “real” impact source is a walking person without shoes and the artificial source is

a standard tapping machine such as that specified in Clause 4, the correlation is not strong.

An alternative method, using a heavy/soft impact source for assessing the impact sound insulation of

a floor against impact sources with strong low-frequency components, such as human footsteps (bare

feet) or children jumping, is given in Annex A. Alternative impact sources (i.e. a proposed modification

of the standard tapping machine to make its dynamic source characteristics similar to those of a person

walking barefoot and a heavy/soft impact source with dynamic source characteristics similar to those

A method to test floor coverings is described in ISO 10140-1:2020, Annex H, for single- or multi-layer

floor coverings installed on specific reference floors. In the case of multi-layer coverings, they can be

The following documents are referred to in the text in such a way that some or all of their content

constitutes requirements of this document. For dated references, only the edition cited applies. For

undated references, the latest edition of the referenced document (including any amendments) applies.

ISO 717-2, Acoustics — Rating of sound insulation in buildings and of building elements — Part 2: Impact

ISO/DIS 10140-1:2020, Acoustics — Laboratory measurement of sound insulation of building elements —

ISO/DIS 10140-4:2020, Acoustics — Laboratory measurement of sound insulation of building elements —

ISO/DIS 10140-5:2020, Acoustics — Laboratory measurement of sound insulation of building elements —

IEC 61260-1, Electroacoustics — Octave-band and fractional-octave-band filters — Part 1: Specifications

ISO and IEC maintain terminological databases for use in standardization at the following addresses:

energy average sound pressure level in a one-third octave band in the receiving room when the floor

Note 2 to entry: The energy average sound pressure level in a room is defined in ISO 10140-4.

impact sound pressure level, L , increased by a correction term which is given in decibels, being ten

times the common logarithm of the ratio between the measured equivalent absorption area, A, of the

Note 2 to entry: The measured equivalent absorption area, A, of the receiving room is defined in ISO 10140-4.

Laboratory test facilities shall comply with the requirements of ISO/DIS 10140-5:2020, Annex A.

The tapping machine shall meet the requirements given in ISO/DIS 10140-5:2020, Annex E.

Requirements for equipment used to measure the sound level, and for calibration of that equipment, are

NOTE Alternative methods using a modified tapping machine or a standard heavy/soft impact source can

provide information suitable for assessing the impact sound insulation of a floor or a floor covering against

common impact sources, for instance a person walking without shoes or a child jumping. Procedures for

measurements using a heavy/soft impact source are given in Annex A, with requirements for alternate impact

Two vertically adjacent rooms are used, the upper one being designated the “source room” and the lower

one the “receiving room”. A floor, which is the test element, separates these two rooms (see Clause 6).

The impact source is placed on top of the test element at different positions and the sound pressure

levels are measured in the receiving room, normally in the frequency range of 100 Hz to 5 000 Hz

(optional down to 50 Hz). The equivalent sound absorption area in the receiving room is calculated from

reverberation time measurements. From the sound pressure levels in the receiving room, the quantities

described in Clause 3 shall be evaluated by taking into account the equivalent absorption area. The

procedures used to determine the energy average sound pressure level corrected for background noise

Precautions should be taken to verify that airborne sound transmission from the source to the receiving

room (including any leakage at the perimeter of the test element) is at least 10 dB below the level of

A method for testing floor coverings is described in ISO/DIS 10140-1:2020, Annex H, for single- or multi-

layer floor coverings installed on specific reference floors. In the case of multi-layer coverings, they

The impact sound shall be generated by the standard tapping machine, as specified in Clause 4. Each set

of measurements should be made with as many impact source positions as necessary to yield a reliable

NOTE When the aim of impact sound insulation measurements is to have a strong correlation between a

“real” impact source (e.g. a person walking or children jumping) and an artificial impact source (e.g. a tapping

machine), both sources apply the same input force spectrum, to ensure the correct ranking of floors and floor

coverings for the “real” and the artificial source, and the impedance spectra of the sources are the same. If the

“real” impact source is a walking person without shoes and the artificial source is a standard tapping machine

An alternative method, using a heavy/soft impact source for assessing the impact sound insulation of

a floor against impact sources with strong low-frequency components, such as human footsteps (bare

feet) or children jumping, is given in Annex A. Alternative impact sources (i.e. a proposed modification

of the standard tapping machine to make its dynamic source characteristics similar to those of a person

walking barefoot and a heavy/soft impact source with dynamic source characteristics similar to those

Also other types of impact sources can be applied, as for example rainfall on roofs and roof elements.

Such sources are defined in ISO 10140-5:2020, Annex H, while the specific application is treated in

When a floor element includes a soft covering, the standard tapping machine shall fulfil special

requirements (specified in ISO/DIS 10140-5:2020, Annex E). If the test surface is covered with an

extremely soft covering or the surface is very uneven, such that the hammers are not able to fall down

the requisite 40 mm to the surface on which the supports rest, pads may be used under the supports to

The impact sound pressure levels can reveal a time dependency after the tapping has started. In such

a case, the measurements should not begin until the noise level has become steady. The measurement

period shall be reported. If stable conditions are not reached after 5 min, the measurements should be

For testing a floor, the tapping machine shall be placed in at least four different positions. The minimum

distance between tapping machine positions shall be at least 0,7 m. The distance of the tapping machine

For heavyweight homogeneous floors, such as solid concrete, the positions and orientation of the

tapping machine shall be randomly distributed over the whole area of the floor under test.

For inhomogeneous floor constructions (such as hollow core concrete slabs or lightweight floors with

ribs, beams, joists, etc.) or floors with rough and/or irregular floor coverings, additional positions

should be used to yield a reliable mean value. The positions shall be randomly distributed on the floor

under test. The line of hammers shall be orientated at 45° to the direction of the beams, ribs or joists

Additional requirements for positioning the tapping machine when testing floor coverings are given in

ISO/DIS 10140-1:2020, Annex H. Each set of measurements (bare floor and covered floor) shall be made

with as many machine positions as necessary to yield a reliable mean value, but the specific locations

and the number of positions depend both on the category of floor covering and on the type of reference

The sound field in the receiving room shall not be affected by the presence of people in the source or

Calculate the normalized impact sound pressure levels (as defined in Clause 3) from the measured (and,

if necessary, corrected-for-background noise) energy average sound pressure levels in the receiving

room and the measured reverberation times, as described in ISO/DIS 10140-4:2020, 4.2, 4.3, 4.5 and 4.6.

If normalized impact sound pressure levels are needed in octave bands, these values shall be calculated

from the three one-third octave band values in each octave band using Equation (2):

Perform all calculations with the appropriate accuracy and present the final results with a precision no

The evaluation of the single-number rating from the results in one-third octave bands shall be done in

In case that the airborne sound transmission from the source to the receiving room cannot be neglected

(this applies to situations where airborne and impact sound pressure level in the receiving room differ

by less than 10 dB, for instance for long reverberation times in the source room or floors with good

impact but poor airborne sound insulation) the measured impact sound shall be corrected. Make the

a) Place the loudspeaker at the edge of the source room at a distance of 1,0 m from the closest wall,

and height of 1,0 m from the floor (both distances are relative to the centre of the loudspeaker).

Only one (1) loudspeaker position is required. With the loudspeaker source on, the resulting sound

pressure level in the source room (L ) and receiving room (L ) shall be measured in one-third

octave bands. From the measured values, calculate the sound pressure level difference, D = L - L .