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Hush Acoustics: How is building soundproofing done?

  • 18 Sep 2023

Soundproofing a building is done in a number of different ways depending on the way the internal walls, floors and ceilings are constructed. For example, are they created mainly using timber, metal frames or masonry/concrete? Hush Acoustics takes a closer look…

This matters because the goal is to add mass and create separation of connected building elements to reduce sound transmission paths through floor and wall structures, as well as preventing sound getting around these structures. Eliminating sound transmission entirely is rarely, if ever, possible, so soundproofing is better thought of as ‘sound reduction’ or an ‘acoustic treatment’.

The level of sound reduction that can be achieved will depend on a number of factors, including the maximum thickness possible for the wall or floor/ceiling construction, budget and whether there is a need to preserve any interior décor features.

The key to success is understanding how to combine the various acoustic insulation products in the correct way. It is here where Hush Acoustics has made it easier to select the right combination through a wide range of fully tested acoustic wall, floor and ceiling systems. 

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These systems are designed to suit many typical types of building construction and floor coverings, including timber floorboards, beam and block and concrete slab floors, as well as timber and metal stud walls and walls of a masonry build. Details of these systems, which are all compliant with the UK Building Regulations covering acoustic performance and suitable for Robust Details projects, are available on the Hush Acoustics website.

What do building soundproofing terms mean?

In order to help inform decisions about how to apply our acoustic wall and floor systems – or any type of sound insulation for that matter – it is important to understand the language of soundproofing. Here we provide a guide to what the most commonly used terms mean.

A-weighting

This is a series of adjustments applied to dB sound measurements to more closely reflect how noise is perceived by the human ear. It is needed because the sensitivity of the ear varies, which means it is most sensitive at frequencies of around 1-6 kHz. A-weighted figures are referred to as dB(A).

Absorption coefficient

This is used to measure and compare the performance of sound absorbers, providing a ratio of the sound energy incident on a surface, to the sound energy absorbed by that surface. Where there is an absorption coefficient of 1, all incident sound energy is absorbed.

Airborne sound

Sound that travels through the air, such as from speech, a television or radio.

Area weight

The area weight is the mass per unit area, measured in kilograms per square metre, which is often used in acoustics to specify materials such as plasterboard, sheathing board or acoustic membrane. It is calculated by multiplying a material’s density by its thickness, and materials with higher area weights will usually provide better sound insulation.

Ctr

This is an adjustment factor which accounts for low frequency noise, which is usually the biggest problem with sound insulation. It reduces the single figure weighted sound reduction level of a building element, according to its ability to block low frequency sound. Elements that are poorer at blocking low frequency sound will have a higher Ctr. The corrective term was originally developed to address the issue of rumbling traffic noise (hence the subscript ‘tr’), but today this term is often specified in situations where low frequency sound may cause annoyance.

Decibel, dB

This is perhaps the most commonly known acoustic value, which refers to the ‘loudness’ of a sound as defined by its intensity (see ‘Intensity’). Human ears can detect intensities from as low as 1×10-12 W/m2, up to a maximum tolerable level of around 1 W/m2. But because our brains interpret sound intensity logarithmically, it is better to relate intensity to the way in which we experience sound and manage this huge range. The following decibel scale is used:

dB = 10 log (I / I0)

– I is the measured intensity

– I0 is the intensity at the threshold of human hearing, 1×10-12 W/m2

Under the decibel scale, human ears can detect sound from 0 dB up to a tolerable 120 dB. Every increase of 10 dB equates to a doubling of the perceived volume.

Direct transmission

This relates to the path that sound takes directly through a separating element, as opposed to flanking transmission which goes around the element.

DnT,w

This is the weighted standardised level difference between two rooms, unlike Rw, which is a site measurement that includes flanking transmission.

Flanking transmission

This describes any path that sound is able to take between two rooms, other than directly through the separating element. 

Floating floor

This is a construction where a continuous resilient layer isolates the finished floor surface  from the structure of the building. The layer absorbs vibration to reduce the transfer of impact noise.

Frequency

The frequency of a sound wave is the number of oscillations per second, measured in Hertz (Hz). Frequency is more commonly thought of as ‘pitch’ treble (high frequency) and bass (low frequency).

IANL

This stands for ‘internal ambient noise level’, i.e. the loudness of background noise in a room.

Impact noise

This is the type of sound that is transferred through the structure of the building by physical contact. It is typically used to describe the noise from footsteps on a floor which transmits to a room below via the floor/ceiling construction, but it is also associated with the noise of rain falling on a roof.

Intensity

A term which describes the sound power per unit area, measured in Watts per square metre (W/m2).

L’nT,w

A measure that relates to impact sound. It is the weighted standardised impact sound pressure level represented as a single-number quantity to characterise the impact sound insulation of floors. To measure this, a ‘tapping’ noise machine is used to hit the floor while the noise level is taken in the room below .

LAeq

LAeq makes it easier to compare varying sound sources or acoustic environments. It does this by taking the total amount of sound energy measured over a defined period, and ‘averaging’ it out, as if the noise was at a constant level the entire time. This is needed because real-world sound sources tend to vary with time, such as a road being noisier at certain times of the day due to increased traffic flow. Hence the need for the ‘equivalent continuous sound pressure level’ or LAeq.

NR

NR, or ‘noise rating’, refers to a series of curves devised by ISO that define maximum permissible dB ratings in each frequency band.

Reverberation time

This is time taken, measured in seconds, for the sound in a room to decay by 60 dB. Where there is a high reverberation time, a high level of echo will occur.

Rw

This is an important measure as it enables us to easily compare construction elements. It is the weighted sound reduction index, in dB, which is measured in specialist laboratories where sound is only able to transfer from one room to another directly, with no flanking transmission. 

Weighted

Given that sound varies by frequency, it can be difficult to compare the performance of different constructions to compare different spectra. Hence why the concept of weighting was devised, giving a single comparable figure with  reference curve matched to the actual spectrum.

Find out more

Hush Acoustics provides specialist technical advice in all areas of building acoustics and soundproofing. The team works with architects, specifiers, contractors, developers and building owners to create acoustic designs that achieve the target performance, as well as supplying all the required materials and components. An installation service can be provided too.

For further information visit www.hushacoustics.co.uk or call 0114 551 8680.

Hush Acoustics Ltd
Unit 2, Tinsley Industrial Estate
Shepcote Way
Sheffield
South Yorkshire
S9 1TH

Tel: 0114 551 8685
Fax: 0151 944 1146

Visit Hush Acoustics' website

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