Communal 51 Ceiling Systems by Vogl

Similar documents
Acoustic ceilings. Creating perfect living spaces. Technical Advice Centre Tel:

REPORT ON THE DETERMINATION OF SOUND ABSORPTION COEFFICIENTS OF BAILEY INTERIORS EXPOSED NU SHADEX PERFORATED PLASTER CEILING TILES (600MM

C09. S02. P02 P14 CasoLine mf

REPORT ON THE DETERMINATION OF SOUND ABSORPTION COEFFICIENTS OF BAILEY INTERIORS CASINO 600MM

REPORT ON THE DETERMINATION OF SOUND ABSORPTION COEFFICIENTS OF BAILEY INTERIORS CELL AIR 1200MM

Custom Audio Designs Ltd

Metal ceilings. OWAtecta. OWAtecta Why metal ceilings. Planning with OWAtecta Variety formation of the ceiling

August 2008: Issue 1. Non - Residential New Build Built-up Metal Roofs

August 2008: Issue 1. Non - Residential New Build Built - up Metal Walls

Demountable suspended grid ceiling system

Guidance on U Values from Domestic Heating Design Guide

CHAPTER 10: Finishes CONTENTS 10.1 PLASTERWORK 10.2 SECOND AND THIRD FIX FINISHES. Chapter 10

URSA ACOUSTIC ROLL URSA GLASSWOOL.

A corridor ceiling system that combines acoustics, aesthetics and accessibility

Resistance to the passage of sound

Resistance to the passage of sound

CasoLine MF Concealed grid MF suspended ceiling system

CEILING TILE. Thermal Mass. Passive Cooling. Thermal Comfort

CHAPTER 10: Finishes CONTENTS 10.1 PLASTERWORK ND AND 3 RD FIX FINISHES

Thermal bridging. Acoustic performance

Reverberation Time Design for IM Building Addition

CO9. Sound absorbing solutions C09

Perforated Plasterboard

June Non - Residential Refurbishment Separating floors

ROCKFON SYSTEM T24 A/E

Demountable suspended grid ceiling system

CASE STUDY OF THE SOUND REDUCTION OF VARIOUS RESIDENTIAL GLAZING TREATMENTS

June Non - Residential New Build Partition walls

CasoLine MF Concealed grid MF suspended ceiling system

Metal ceilings. OWAtecta. OWAtecta Why metal ceilings. Planning with OWAtecta Variety formation of the ceiling

June Residential Refurbishment Separating walls

Suspended timber upper floors

From September Product Catalogue

Built-up metal walls. Built-up metal wall design. 3.3 Built-up Metal Walls

ROCKFON SYSTEM T24 A/E

All panels can be supplied in a range of styles, to suit the applications pictured below.

Approved Document E Technical Design Report

Selecting floors and ceilings

Specialists in Acoustic Flooring and House to Flat Conversions

Cooling and heating systems. Contact cooling ceiling system KKS-4/GK for gypsum board ceilings

How glass or rock mineral wool works in a wall or floor cavity

June Residential Refurbishment Separating floors

SIDERISE FLX flexible acoustic barriers for suspended ceilings

Absorb-R ToughSound. Datasheet

Relationship between flanking noise through a common ceiling plenum and plenum absorption George van Hout, John Pearse and Brian Donohue

19 th INTERNATIONAL CONGRESS ON ACOUSTICS MADRID, 2-7 SEPTEMBER 2007 A METHODOLOGY TO MEASURE THE ACOUSTIC PERFORMANCE OF ACCESS FLOORS

ACOUSTIC BARRIERS DWX SERIES FOR DUCTWORK

AtlasPantou (Properties) Ltd

Gyproc Lay-in Grid Ceilings

Unit 8 Walls & Partition

SOUND INSULATION TESTING IN DWELLINGS

FERMACELL DRY FLOORING ELEMENTS: IMPROVED LIVING CONDITIONS THROUGH BETTER ACOUSTIC AND THERMAL INSULATION. Dry Lining

April Section 2.4. Built-up Metal Roofs

Division 09 FINISHES TABLE OF CONTENTS

ROCKFLOOR. Thermal and acoustic stone wool insulation for ground and separating floors

April Section 3.3. Built-up Metal Walls

Acoustic Performance of Light Steel Framed Systems

URSA MINERAL WOOL URSA Acoustic Roll

Metal Web Floor System

SAS International Ltd. System 120 By SAS International Ltd. Product summary page for System 120 generated by ribaproductselector.

May 2012 C1/SfB (35) R17. Gyptone Access Hatch Trap Guide. Rapid access system for corridor above-ceiling services

(A copy of this Appendix is available on /)

SOUNDSCAPES SHAPES ACOUSTICAL CLOUDS

April Section 4.3. Separating Floors

CONSIDERATIONS ON THE AIRBORNE SOUND INSULATION OF A MODERNISED HOTEL

T-Barrier System. Masonry Applications. Satisfying Fire, Thermal and Acoustic Requirements at the Combined Party Wall and Pitched Roof Junction

Section 11 FIRE STOPPING

ReSound Acoustic panels, rafts and baffles

Pladur FON+ Systems. Acoustic conditioning solutions FON + Acoustic Solutions

ACOUSTIC INFILLS High performance sound absorption for perforated metal decks

SOUND INSULATION DESIGN OF MODULAR CONSTRUCTION HOUSING

URSA Acoustic Roll Acoustic Insulation for Floors and Walls

Independent twin frame high performance acoustic separating wall system

ROCKWOOL FLEXI Insulation Application Guide

Knauf C-Form Suspended Ceilings

C05. S03. P02 P08 FireWall

Measurement of Airborne & Impact Sound Insulation. University of Durham, Pavilion H, Howlands Farm, Durham.

Perforated Plasterboard Range CELEBRATING. Building business together since 1966 YEARS

FIRE PROTECTION. GTEC Shaftwall systems 244 GTEC Shaftwall Stairwell systems 248 GTEC Horizontal Shaftwall systems 249 GTEC Encasement systems 250

CasoLine GRID. Suspended grid ceiling system. The Manchester Academy

1.0 INTRODUCTION BUILDING REGULATIONS SOUND INSULATION REQUIREMENTS TEST PROCEDURE AND ANALYSIS...3

CI/SfB V. Fellert Spray Applied Acoustic Plastering System. Highly absorbent plaster to improve sound surroundings

From September Product Catalogue

Cavity fire barriers. Cavity fire barriers. Fire separation within concealed spaces. C06 Floors and ceilings

SCHEDULE OF BUILDING OPERATIONS

Gyptone GRID Suspended grid ceiling system

SECTION ACOUSTICAL CEILINGS

NORTILE LAV-IN, LAY-ON. Metal Ceilings

Patent Application No :

INSULATING CONCRETE FORMWORK SYSTEM

September Reflex Bearers

Enhancing Acoustic Performance through the use of Window Shade Fabric White Paper

Ceilings without Filler. VoglFuge. Create perfect acoustic designer ceilings with the VoglFuge system. with air purification effect as standard

CI/SfB. June RockLink 24 Monolith. Installation system

Part E robustdetails. robustdetails. January 2018 Update Pack

NEWS LETTER MARCH 27, 2009

ACOUSTIC METAL CEILINGS

T-Barrier System. Timber Frame Applications. Satisfying Fire, Thermal and Acoustic Requirements at the Combined Party Wall and Pitched Roof Junction

SIDERISE CBX flexible acoustic barriers for suspended ceilings

Transcription:

33 commercial connections LIMITED Sound and thermal insulation specialists Communal 51 Ceiling Systems by Vogl Designed to meet Regulations Northern Ireland Regulation 51 Part G 2012 Republic of Ireland Regulation E2 TGDE 2014 England/Wales Regulation 1 E3 ADE

Reverberation in Communal Areas Vogl Communal 51Q Vogl Communal 51R Reverberation in the common internal parts of buildings containing flats, maisonettes or rooms for residential purposes are now required to have reduced noise levels from reverberation to protect residents from possible excessive noise nuisance. These common areas tend to be constructed with hard, reflective, durable surfaces for maintenance purposes. Introducing the Vogl Perforated Absorption Ceilings into these areas helps absorb the reflected energy being created by the durable surfaces and thus reducing the level of noise for the dwelling occupants. Regulations offer two methods of showing compliance with: Method A Method B 2

Nearly Invisible Access Hatches Corridor acoustic ceilings usually have more than one function. The ceiling void often is used to accommodate other mechanical and electrical installations, such as lighting, air conditioning, or sprinkler systems. Access panels are necessary to make these services accessible for inspection or maintenance. Vogl systems offer unbeatable aesthetically pleasing access hatches that can be used not only with Vogl boards but, with care and understanding, any make of plasterboard lining systems. Access hatch 3

Guidance Specification: Vogl Communal 51 Perforated Absorption ceiling system. Board suspended ceiling system Vogl Communal Area Absorption Ceiling Type Suspended Fix Irish Distributor Commercial Connections Ltd Phone: +44 28 4483 1227 Product reference: Vogl Communal 51 Q or R (delete as appropriate) absorption ceiling system incorporating 30mm RWA 45 mineral wool Ceiling Boards: 12.5mm thick perforated engineered plasterboard, in accordance with EN 14190 with air purification effect Download Standard Ceiling Detail CAD Perforation: Communal 51 Q or R (delete as appropriate) covered on reverse side with black sound absorbing fleece. (Note: Q equals quadrate profile. R equals round profile) Soffit height above finished floor level: varies Grid type Zinc plated steel profiles, as primary and secondary profiles in accordance with EN 141195 and in accordance with EN 13964 Suspension system Grid centres: Maximum spacing recommended by manufacturer. Download Standard Insulated Ceiling CAD Primary profile centres: Maximum spacing recommended by manufacturer. 4

Secondary profile centres: Maximum spacing recommended by manufacturer maximum. Hanger Centres: Maximum spacing recommended by manufacturer. Top fixings to be selected by installer. Protective finish to suspension systems Galvanised. Perforated acoustic boards to be laid edge to edge, tightly butt jointed and fixed to the suspension grid with Vogl Narrow Head screws at maximum 170mm centres. Sound absorption Class C with 30mm thick RWA mineral fibre quilt to be loose-laid over back of ceiling membrane. Minimum void depth 65mm. Download Timber Ceiling CAD Access Access panels if indicated on drawing. Vogl proprietary access panels, size as indicated on drawing. Panel complete with Vogl push-lock mechanism and wire safety restraint. Finish/Colour By others in accordance with architect s layouts. Paint to be roller applied only, acoustic ceiling is not to be spray painted. Integrated service fittings Any services e.g. lights, exceeding 0.50 Kg shall be independently suspended. Other requirements All Vogl system components shall be installed in accordance with current Vogl installation instructions. Download Timber Insulated Ceiling CAD 5

Method A: Cover a specified area with an absorber of an appropriate class that has been rated according to BS EN ISO 11654. For entrance halls, corridors or hallways cover an area equal to or greater than the floor area with a Class C absorber or better. It will normally be convenient to cover the ceiling area with the additional absorption. Method A can generally be satisfied by the use of proprietary acoustic ceilings; however, the absorptive material can be applied to any surface that faces into the space. For stairwells or a stair enclosure, calculate the combined area of the stair treads, the upper surface of the intermediate landings, the upper surface of the landings (excluding ground floor) and the ceiling area of the top floor. Either cover at least an area equal to this calculated area with a Class D absorber, or cover an area of at least 50% of this calculated area with a Class C absorber or better. The absorptive material should be equally distributed between all floor levels. It will normally be convenient to cover the underside of intermediate landings, the underside of the other landings, and the ceiling area on the top floor. Corridor Entrance Hall Stairwell Finished Surfaces Floors Tiles Wall Plastered Ceiling Plasterboard Worked Example for Entrance Halls and Corridors Entrance Hall m²: Ground Floor: First Floor: Second Floor: Total Corridor m²: Ground Floor: First Floor: Second Floor: Total 3.10 x 4.16 = 12.90² 3.10 x 4.16 = 12.90² 3.10 x 4.16 = 12.90² 38.70m² (4.75 x 1.84) + (5.845 x 1.2) = 15.75m² (4.75 x 1.84) + (5.845 x 1.2) = 15.75m² (4.75 x 1.84) + (5.845 x 1.2) = 15.75m² 47.25m² Stairwell m²: Total Treads: 38 Intermediate landing area: 2 x (1 x 2.225) = 4.40m² Tread Area: Total tread area: 1 x 0.25 = 0.25m² 38 x 0.25 = 9.50m² First Floor landing area: Second Floor landing area: Ceiling area top floor: 0.945 x 2.225 = 2.10m² 0.945 x 2.225 = 2.10m² 4.42 x 2.225 = 9.83m² 6

Method B: Determine the minimum amount of absorptive material using a calculation procedure in octave bands. Method B is intended only for corridors, hallways and entrance halls, as it is not well suited to stairwells. For ease of understanding and to simplify specification of materials to meet this requirement, sound absorption performance has been classified from A through to E according to BS EN ISO 11654, with A being the highest level of absorption (see appendices). In comparison with Method A, Method B takes account of the existing absorption provided by all surfaces. In some cases, Method B should allow greater flexibility in meeting Regulation 51 and require less additional absorption than Method A. For an absorptive material of surface area, S in m 2, and sound absorption coefficient α the absorption area A is equal to the product of S and α. The total absorption area AT, in square metres is defined as the hypothetical area of a totally absorbing surface, which if it were the only absorbing element in the space would give the same reverberation time as the space under consideration. For n surfaces in a space, the total absorption area, AT, can be found using the following equation AT = α1s1 + α2s2 +... + αnsn For entrance halls, provide a minimum of 0.20 m 2 total absorption area per cubic metre of the volume. The additional absorptive material should be distributed over the available surfaces. For corridors or hallways, provide a minimum of 0.25m 2 total absorption area per cubic metre of the volume. The additional absorptive material should be distributed over one or more of the surfaces. Absorption areas should be calculated for each octave band. Regulation 51 will be satisfied when the appropriate amount of absorption area is provided for each octave band between 250Hz and 4000Hz inclusively. Absorption coefficient data (to two decimal places) should be taken from the following: a) For specific products, use laboratory measurements of absorption coefficient data determined using BS EN 20354. The measured third octave band data should be converted to practical absorption coefficient data, αp in octave bands, according to BS EN ISO 11654; or b) For generic materials, use Table 7.1. This contains typical absorption coefficient data for common materials used in buildings. This data may be supplemented by published octave band data for other generic materials. In Method B, each calculation step is to be rounded to two decimal places. 7

Table 7.2 Example calculation for an entrance hall (Method B) Step 1: Calculate the surface area related to each absorptive material (i.e. for the floor, walls, doors and ceiling). Surface Surface finish Area m 2 Floor Doors Walls (excluding door area) Window Ceiling Glazed tile Timber Plastered Masonry Glazing To be determined from this calculation Step 2: Obtain values of absorption coefficients for the carpet, painted concrete block walls and the timber doors. In this case, the values are taken from Table 7.1. Surface Floor Doors Walls Window Ceiling 15.75 9.45 61.43 1.08 Absorption coefficient (α) in octave frequency bands Area 250Hz 500Hz 1000Hz 2000Hz 4000Hz m 2 15.75 0.01 0.01 0.01 0.02 0.02 9.45 0.10 0.08 0.08 0.08 0.08 25.40 0.05 0.06 0.07 0.09 0.08 1.08 0.08 0.05 0.04 0.03 0.02 15.75 To be determined from this calculation Step 3: Calculate the absorption area (m 2 ) related to each absorption surface (i.e. for the floor, walls and doors) in octave frequency bands (Absorption area = surface area x absorption coefficient). Surface 250Hz 500Hz 1000Hz 2000Hz 4000Hz Floor Doors Walls Window 0.36 (12.0 x 0.03) 0.96 (9.60 x 0.10) 1.27 (25.40x 0.05) 0.086 (1.08x0.08) 0.72 0.77 1.52 0.054 1.80 0.77 1.78 0.043 3.60 0.77 2.29 0.032 4.80 0.77 2.03 0.022 Step 4: Calculate the sum of the absorption area (m 2 ) obtained in Step 3. 250Hz 500Hz 1000Hz 2000Hz 4000Hz Total absorption area (m 2 ) 2.67 (0.36 + 0.96 + 1.27+0.086) 3.06 4.39 6.69 7.62 Step 5 Calculate the total absorption area (AT) required for the corridor. The volume is 43.9m 3 and therefore 0.25 x 43.940 = 10.98 m 2 of absorption area is required. A T (m 2 ) 10.98 Step 6: Calculate additional absorption area (A) to be provided by ceiling (m 2 ). If any values of minimum absorption area are negative, then there is sufficient absorption from the other surfaces to meet the requirement without any additional absorption in this octave band: (Additional absorption = A T total absorption area (from Step 5)). 250Hz 500Hz 1000Hz 2000Hz 4000Hz Additional absorption area (m 2 ) 8.31 7.92 6.59 4.29 3.36 (10.98 2.67) NB Negative values indicate that no additional absorption is necessary. Step 7: Calculate required absorption coefficient (α) to be provided by ceiling: (Required absorption coefficient α = Additional absorption area area of ceiling). 250Hz 500Hz 1000Hz 2000Hz 4000Hz Required absorption coefficient (α) 0.28 (3.41 12.00) 0.25 0.14 Any value Any value Step 8: Identify a ceiling product from manufacturer s laboratory measurement data that provides absorption coefficients that exceed the values calculated in Step 7. 8

Table 7.1 Absorption coefficient data for common materials in buildings Sound absorption coefficient, α in octave frequency bands (Hz) Material 63Hz 125Hz 250Hz 500Hz 1KHz 2KHz 4KHz 8KHz Communal 51 Q with 65mm minimum 0.20 0.50 0.80 0.90 0.80 0.70 0.70 void and 30mm mineral wool Communal 51 Q with 65mm minimum 0.25 0.50 0.70 0.80 0.75 0.65 0.60 void and 30mm mineral wool Fair faced concrete or plastered 0.01 0.01 0.02 0.02 0.03 masonry Fair faced brick 0.02 0.03 0.04 0.05 0.07 Painted concrete block 0.05 0.06 0.07 0.09 0.08 Windows, glass façade 0.08 0.05 0.04 0.03 0.02 Doors (timber) 0.10 0.08 0.08 0.08 0.08 Glazed tile/marble 0.01 0.01 0.01 0.02 0.02 Hard floor coverings (e.g. lino, parquet) 0.03 0.04 0.05 0.05 0.06 on concrete floor Soft floor finish (e.g. carpet, foam 0.03 0.06 0.15 0.30 0.40 backed vinyl) on concrete floor Suspended plaster or plasterboard ceiling (with large air space behind) 0.15 0.10 0.05 0.05 0.05 Sound Absorption Classification: The sound absorption coefficient alpha (α) is used to measure sound absorption, returning a value between 0 and 1.00. Zero is no absorption (total reflection), and 1.00 is total absorption of the incident sound. Materials are rated from A to E to allow for quick and easy comparison of acoustic performance, with A-class absorption providing the highest rated sound absorption. Standard test frequencies are used to return the absorption coefficient of a material, in accordance with BS EN ISO 354. These results are used to produce an absorption curve on a graph. The material s sound absorption class determined by comparing the values against a reference curve, giving an A weighted sound absorption coefficient (α w ) calculated in accordance with BS EN ISO11654. Class A Class B Class C Class D Class E Sound absorption table Highest Lowest 9

2024 © businessdocbox.com Privacy Policy | Terms of Service | Feedback