A.T. 2.1 Architectural Technology Daniel Lomax - C3310227 Matthew Riley - C3339937 Aidan Lewis Bintcliffe - C3254105
Contents Page 1
Project Description
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Structural System
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Construction Sequence
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Material, Construction and Detailed design
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Fire Strategy
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Environmental Consideration - Site
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Environmental Consideration - Programme
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Environmental Systems - Heating, Cooling and Ventilation
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Environmental Systems - Lighting
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Sustainability - Environment
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Conclusion
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References
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PROJECT DESCRIPTION
MAGGIE’S LOCATIONS
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Highlands
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Glasgow
Dundee Fife Edinburgh
Lanarkshire North East
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Since the opening of the first Maggie’s Centre in Edinburgh in 1996, Maggie’s has grown and developed a series of innovative and remarkable buildings designed by world class architects. Whilst contemporary architecture has a reputation, sometimes deservedly, for being at times cold or alienating, each Maggie’s Centre, whether in Glasgow, London, or Hong Kong, provides a space where people feel at home and cared for, spaces which are warm, receptive, and welcoming There is currently 12 Maggie’s Centres located across britain and 3 planned centres abroad, architectural they all abide by a certain set of rules set in place by the Maggie’s founders that all buildings must be designed around a central kitchen to create feeling of home and community.
Nottingham
Cotswolds South West Wales
Oxford London
The Maggie’s centre Gartnavel Glasgow is the only building to deviate from this scheme and revolve around a central garden
PROJECT DESCRIPTION
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Client : Maggie Keswick Jencks cancer caring centres trust Project : Maggies cancer caring centre Location : Glasgow, Scotland Site Location : Gartnavel General Hospital, Glasgow, on a green area adjacent to the Gartnavel Royal Hospital East House, a Category A listed Building Architect : OMA Project Architect : Richard Hollington Implementation Architects : Keppie Structure : Sinclair knight Merz Services : Kj Tait engineers Landscape : Lily jencks
Project Dates : Build completed september 2011, opened to public October 2011 Program Details : 534m2 comprising counselling rooms, sitting rooms, offices and a large multi-purpose space. Located near the Beatson West of Scotland Cancer Centre, the second largest oncology centre in the UK, the new Maggie’s Centre Gartnavel provides a space for practical and emotional support for people with cancer, their families and friends Cost of build : £2.8 million
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The aim of a Maggie's Centre is to provide an environment of practical and emotional support for people with cancer, their families and friends. Since the opening of the first Maggie's Centre in Edinburgh in 1996, the Maggie's Cancer Caring Centres foundation has grown substantially, commissioning and developing a series of innovative buildings designed by world class architects. Maggie's Centre approached OMA to design a new centre on the grounds of Gartnavel hospital in Glasgow, close to the Beatson West of Scotland Cancer Centre. OMA designed a single-level building in the form of a ring of interlocking rooms surrounding an internal landscaped courtyard. Seemingly haphazardly arranged, the building is a careful composition of spaces responding to the needs of a Maggie's Centre and providing a refuge for those coping with cancer. The main goal was to provide a space where people feel at home and cared for, a space that is warm, receptive, and welcoming.
AWARDS
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This is an extraordinary building – a place of calm, simultaneously welcoming and open. Maggie’s Centres provide support for people with cancer, their families and friends. Exceptional architecture and innovative spaces make people feel better. This single-level building, a ring of interlocking rooms, is close to the Beatson Cancer Centre. The spaces feel casual but allow for privacy. The approach is about modest external expression, embracing a courtyard garden to generate a unique place of gentle contemplation and an exemplary caring environment.
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The full judges citation for the winning project
RIAS Andrew Doolan Best Building in Scotland Award 2012 RIAS GOLD MEDAL £25,000
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OMA generously donated their £25,000 prize to the Maggie’s Cancer Care Center
AWARDS
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We are absolutely delighted that Maggie’s Glasgow Gartnavel has been shortlisted for the Stirling. It’s an honour and a privilege to be up against such world class architects. Working with Rem Koolhaas was a privilege and he has created a building for people with cancer that is beautiful, uplifting and inspired. Whatever the outcome we are very proud of Maggie’s Gartnavel. Maggie’s Chief Executive Laura Lee
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The RIBA Stirling Prize. The RIBA Stirling Prize is awarded to the architects of the building which has made the greatest contribution to British architecture in the past year. The award, established in 1996, is considered the most prestigious award in British architecture.
SITE PLAN
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Location was specifically selected for its semi-wooded, natural landscape, the design of the centre takes full advantage of the natural surroundings and potential of the site. Already a green area within the hospital grounds, the landscape design further enhances the current landscape, benefiting not just those visiting the Maggie’s Centre but all who come to the hospital grounds through additional planting and greening of the site.
SURROUNDING BUILDINGS
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1. Maggie’s Cancer Caring Centre
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2. East House 3. Renal unit
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5. Gartnavel Royal
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Every window of the structure encompasses an element of greenery. the architect worked closely with the landscape to ensure the angles were sufficient enough for patients to not be able to see the surrounding hospital buildings. A place for treatment and care with out the reminders or feel of a hospital environment
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6. Beatson Oncology Unit
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PLAN
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SECTION A-A
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A
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SECTION B-B
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B
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SECTION C-C
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NORTH ELEVATION
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EAST ELEVATION
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SOUTH ELEVATION
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WEST ELEVATION
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SCHEDULE OF ACCOMMODATION
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SCHEDULE OF ACCOMMODATION
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SCHEDULE OF ACCOMMODATION
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SCHEDULE OF ACCOMMODATION
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SCHEDULE OF ACCOMMODATION
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SCHEDULE OF ACCOMMODATION
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SCHEDULE OF ACCOMMODATION
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SCHEDULE OF ACCOMMODATION
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SCHEDULE OF ACCOMMODATION
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SCHEDULE OF ACCOMMODATION
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SCHEDULE OF ACCOMMODATION
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SCHEDULE OF ACCOMMODATION
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SCHEDULE OF ACCOMMODATION
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SCHEDULE OF ACCOMMODATION
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SCHEDULE OF ACCOMMODATION
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PHYSICAL MODEL
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Creating a physical model allowed us to gain a greater understanding of the internal spaces and how circulation with in the building would work, also enhancing our perception of how the building relates to the contours of the site A series of overlapping and interlocking rooms, each with its own specific programmatic use. Playfully and seemingly haphazardly arranged, the building is a carefully considered composition of spaces arranged around an inner landscaped courtyard
PHYSICAL MODEL
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Through a minimal amount of spatial definition, L-shaped figures in plan create clearly distinguished zones of different programmatic use. The arrangement of rooms minimises the need for corridors and hallways allowing the rooms to flow from one to another as opposed to a series isolated rooms. At the same time the design also provides moments spaces for more private and personal conversations – either in the intimate setting of the counselling rooms, or in smaller nooks and private spaces contained in the design
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STRUCTURAL SYSTEM
PRIMARY STRUCTURE 1
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4 concrete columns in total aide in supporting the roof structure transferring loads into the foundations.
3 columns in the large room help to support the section of the roof lacking in support from the internal walls
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1 column in the kitchen helps with structural loading where surrounding walls are not great enough to support the roof alone
PRIMARY STRUCTURE 1
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Plan highlighting the primary structural internal walls that create 7 internal spaces, this part of the structure combined with the 4 columns support the concrete roof
PRIMARY STRUCTURE 1
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The structure is supported by concrete slab raft foundations, this type of foundation spreads loads from the structure over a large area. Raft foundations aide in reducing differential settlements as the concrete slab resists differential movements between loading positions.
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Raft foundations are required on soft soils with low bearing capacity as they spread the load over a greater area.
PRIMARY STRUCTURE 1
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The structure consists of reinforced concrete walls that act as the primary support system for the roof. The insulation has been placed inside of the wall to retain the effect of exposed concrete inside and out.
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PRIMARY STRUCTURE 1
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The structure consists of 4 load bearing columns 2 of which have been positioned inside of cupboards out of site this aides the internal walls in supporting the roof
PRIMARY STRUCTURE 1
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The structure is comprised of a concrete roof that is supported by the primary load bearing columns and internal concrete walls, the roof is inlaid with beech plywood planks cast into the concrete
SECONDARY STRUCTURE 1
The glazing in the structure is non load-bearing.
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Slimline frames have been used to give an almost frameless effect, so as not to detract from the expansive vistas. The glazing continues vertically above the ceiling level, giving the effect of almost non-existent glazing.
SECONDARY STRUCTURE 1
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Section highlighting the expansive use of glazing, spanning the floor to the roof in height
DEAD LOAD DIAGRAM 1
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DEAD LOAD DIAGRAM 1
The structural load from the roof spreads out across the entire surface of the roof.
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DEAD LOAD DIAGRAM 1
The loads are directed towards the columns and the in situ walls.
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DEAD LOAD DIAGRAM 1
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DEAD LOAD DIAGRAM 1
The loads are then taken down the columns and in situ walls
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DEAD LOAD DIAGRAM 1
Towards the foundations
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DEAD LOAD DIAGRAM The dead loads taken by the columns are then taken into the raft foundations. The columns were required in this area as the glazing gap was far to great for the in situ walls to take the entire loading of the roof.
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DEAD LOAD DIAGRAM 1
The loads taken by the in situ walls are also taken into the raft foundations
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DEAD LOAD DIAGRAM 1
The structural load is then taken through the foundations
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DEAD LOAD DIAGRAM 1
Then dispersed into the ground.
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LIVE LOADS DIAGRAM 1
The live loads are non structural weight acting upon the building include people, objects and the elements such as wind, snow and rain
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LIVE LOADS DIAGRAM 1
The live load of an object is placed upon the structure.
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LIVE LOADS DIAGRAM 1
The live load of an object is then taken by the surface and dispersed horizontally.
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LIVE LOADS DIAGRAM 1
The live load of an object is then taken by the surface and dispersed vertically through the concrete floor.
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LIVE LOADS DIAGRAM 1
The load is taken by the ground from the concrete floor.
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LIVE LOADS DIAGRAM 1
The load is then dispersed into the earth and spread horizontally.
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LIVE LOADS DIAGRAM The load is then dispersed vertically down into the earth.
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The forces acting upon the structure alter daily particularly in public areas where number of people can increase and decrease.
LIVE LOADS DIAGRAM 1
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CONSTRUCTION SEQUENCE
CONSTRUCTION EXPLODED AXONOMETRIC 1 2
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GROUND LEVEL 1 2
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EXCAVATION OF GROUND 1
Construction commenced in mid September on site, with tree removal and site clearance work completed by end of week two. Excavations for reduce dig to building footprint were then carried out
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BASEMENT WATERPROOFING 1 2
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BASEMENT IN SITU 1
Week three of construction saw the basement excavation and the base concrete slab was cast. The concrete used for the basement was constructed with a Caltite admixture for water proofing purposes and the basement walls were cast in situ using Peri Vario formwork
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BASEMENT INSULATION 1 2
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BASEMENT STAIRS 1 2
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HARDCORE LAYER ADDED 1 2
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WATERPROOF MEMBRANE ADDED 1 2
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CONCRETE FOUNDATIONS 1 2
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INSULATED VOID FORMER 1 2
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1200 GAUGE VISQUEEN SEPARATING MEMBRANE 1 2
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FLOOR POUR 1
As the building is a series of linked rooms at different levels the ground floor structural slab was cast in four separate concrete pours
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FLOOR POUR 1 2
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FLOOR POUR 1 2
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FLOOR POUR 1 2
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PRIMARY LOADING STRUCTURES 1 Formwork for the subsequent concrete pours to the upper ground floor walls constructed with a target to have these completed by late December
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INSULATION 1 2
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PRECAST PANELS 1 2
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PATH AND COURTYARD BASE 1 2
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SHELVING INCASES SUPPORTIVE COLUMNS 1 2
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ROOF SECTION 1 2
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BALCONY 1 2
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ALUMINIUM FRAMES 1 2
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GLAZING 1 2
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MATERIAL, CONSTRUCTION AND DETAILED DESIGN
MATERIALS 1
Sanded and oiled natural elm in medium counselling room.
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Kvadrat Dir 4-211 curtain fabric
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Altro screwed Quartz Boutique tourmaline flooring
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Pre-cast concrete with masterseal 303 antigraffiti coating
Polyester resin with sanded finish - built in furniture to large room
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Polyester resin built in furniture with sanded finish to kitchen
45.5mm double glazed unit with low-e coating
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Satin anodised aluminium (door and window frames and floor trench heating grilles)
LOCATION OF DETAIL 1 2 3
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DETAIL 1 2 3
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MATERIAL - Ground The ground is excavated ready for initial build to commence on site
DETAIL 1 2 3
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MATERIAL - Water proof membrane
DETAIL 1 2 3
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MATERIAL - 450 in situ concrete floor slab with in situ concrete up stand
DETAIL 1 2 3
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MATERIAL - EPDM cover flashing This is by sub contractor design to lap with vertical damp proof membrane
DETAIL 1 2 3
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MATERIAL - External insulation Protects the membrane
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DETAIL 1 2 3
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MATERIAL - Neopreme spacer
DETAIL 1 2 3
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MATERIAL - Aluminium Frame up stand
DETAIL 1 2 3
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MATERIAL - Neopreme space
DETAIL 1 2 3
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MATERIAL - Insulation inside aluminium up stand
DETAIL 1 2 3
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MATERIAL - Aluminium retention to gravel bed
DETAIL 1 2 3
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MATERIAL - Aluminium glazing frame
DETAIL 1 2 3
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MATERIAL - Double glazing panels
DETAIL 1 2 3
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MATERIAL - Gravel bed
DETAIL 1 2 3
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MATERIAL - L section down stand galvanised mild steel for floor grill
DETAIL 1 2 3
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MATERIAL - Galvanised mild steel edge
DETAIL 1 2 3
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MATERIAL - Insulated void former and pocket for trench heating system
DETAIL 1 2 3
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MATERIAL - Trench heating system
DETAIL 1 2 3
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MATERIAL - Mild steel grille support frame
DETAIL 1 2 3
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MATERIAL - parallel mild steel grille
DETAIL 1 2 3
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MATERIAL - perpendicular mild steel grille
DETAIL 1 2 3
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MATERIAL - 150mm floating floor slab
DETAIL 1 2 3
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MATERIAL - resin coating finish
LOCATION OF DETAIL 1 2 3
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DETAIL 1 2 3
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MATERIAL - Concrete cantilevered balcony slab cast in situ 300mm deep
DETAIL 1 2 3
4 5 6 7 8 9 10 MATERIAL - Vapour barrier
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DETAIL 1 2 3
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MATERIAL - Timber baton
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required to hold vapour barrier in place and to attach the aluminium flashing trim to
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DETAIL 1 2 3
4 5 6 7 8 9 10 MATERIAL - 450 x 50 aluminium edge trim
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DETAIL 1 2 3
4 5 6 7 8 9 10 MATERIAL - Purpose made aluminium support frame
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DETAIL 1 2 3
4 5 6 7 8 9 10 MATERIAL - Purpose made aluminium support frame
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DETAIL 1 2 3
4 5 6 7 8 9 10 MATERIAL - Purpose made aluminium support frame
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DETAIL 1 2 3
4 5 6 7 8 9 10 MATERIAL -267 x 83 Aluminium edge trim
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DETAIL 1 2 3
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MATERIAL - Insulation
DETAIL 1 2 3
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MATERIAL - Aluminium L section for grille build up
DETAIL 1 2 3
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MATERIAL - Waterproofing membrane
DETAIL 1 2 3
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MATERIAL - Galvanised mild steel grill support section
DETAIL 1 2 3
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MATERIAL - Galvanised mild steel grill support frame
DETAIL 1 2 3
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MATERIAL - Galvanised mild steel grill parallel
DETAIL 1 2 3
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MATERIAL - Galvanised mild steel grill perpendicular
DETAIL 1 2 3
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MATERIAL - Neopreme spacer
DETAIL 1 2 3
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MATERIAL - balustrade support
DETAIL 1 2 3
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MATERIAL - Galvanised PPC Balustrade
DETAIL 1 2 3
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MATERIAL - 70mm insulated void former
DETAIL 1 2 3
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MATERIAL - 1500 gauge visqueen separating membrane
DETAIL 1 2 3
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MATERIAL - 150mm concrete floating floor slab
DETAIL 1 2 3
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MATERIAL - Resin coating for external use
LOCATION OF DETAIL 1 2 3
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DETAIL 1 2 3
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MATERIAL - Beech planks
DETAIL 1 2 3
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MATERIAL - 345mm reinforced concrete roof slab
DETAIL 1 2 3
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MATERIAL - Timber spacers
DETAIL 1 2 3
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MATERIAL - Water proof membrane
DETAIL 1 2 3
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MATERIAL - Aluminium Frame for glazing fixing
DETAIL 1 2 3
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MATERIAL - Timber spacer
DETAIL 1 2 3
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MATERIAL - Timber spacer
DETAIL 1 2 3
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MATERIAL - Glazing fixing system
DETAIL 1 2 3
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MATERIAL - Double glazed panels
DETAIL 1 2 3
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MATERIAL - Insulation
DETAIL 1 2 3
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MATERIAL - Aluminium support frame for glazing
DETAIL 1 2 3
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MATERIAL - Insulation
DETAIL 1 2 3
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MATERIAL - Damp proof membrane
DETAIL 1 2 3
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MATERIAL - Adjustable support for concrete planks
DETAIL 1 2 3
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MATERIAL - Concrete planks laid to mirror the beech planks
DETAIL 1 2 3
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MATERIAL - Aluminium flashing trim
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FIRE STRATEGY
FIRE ALARM LOCATIONS 1 2 3 4
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SMOKE & HEAT DETECTOR LOCATIONS 1 2 3 4
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FIRE DOORS 1 2 3 4
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MEANS OF ESCAPE Circle highlighted doors denote the principle access & egress points
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HABITABLE ROOMS & AREAS 1 2 3 4
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ESCAPE ROUTES & TRAVEL DISTANCES From any point within the grey circles a user can escape out of either of the exit doors (highlighted red) within the 18m maximum travel distance.
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ENVIRONMENTAL CONSIDERATIONS - SITE
WIND ANALYSIS 1 2 3 4 5
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SOLAR ANALYSIS 1 2 3 4 5
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AVERAGE RAINFALL GLASGOW PER MONTH (MM) 1 2 3 4 5
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AVERAGE TEMPERATURE GLASGOW PER MONTH 1 2 3 4 5
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SOLAR SHADING SUMMER EQUINOX 1 2 3 4 5
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SOLAR SHADING WINTER EQUINOX 1 2 3 4 5
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SUMMER SOLSTICE SHADOWS 1 2 3 4 5
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8:00am
SUMMER SOLSTICE SHADOWS 1 2 3 4 5
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9:00am
SUMMER SOLSTICE SHADOWS 1 2 3 4 5
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10:00am
SUMMER SOLSTICE SHADOWS 1 2 3 4 5
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11:00am
SUMMER SOLSTICE SHADOWS 1 2 3 4 5
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12:00pm
SUMMER SOLSTICE SHADOWS 1 2 3 4 5
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01:00pm
SUMMER SOLSTICE SHADOWS 1 2 3 4 5
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02:00pm
SUMMER SOLSTICE SHADOWS 1 2 3 4 5
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03:00pm
SUMMER SOLSTICE SHADOWS 1 2 3 4 5
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04:00pm
WINTER SOLSTICE SHADOWS 1 2 3 4 5
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8:00am
WINTER SOLSTICE SHADOWS 1 2 3 4 5
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9:00am
WINTER SOLSTICE SHADOWS 1 2 3 4 5
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10:00am
WINTER SOLSTICE SHADOWS 1 2 3 4 5
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11:00am
WINTER SOLSTICE SHADOWS 1 2 3 4 5
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12:00pm
WINTER SOLSTICE SHADOWS 1 2 3 4 5
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01:00pm
WINTER SOLSTICE SHADOWS 1 2 3 4 5
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02:00pm
WINTER SOLSTICE SHADOWS 1 2 3 4 5
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03:00pm
WINTER SOLSTICE SHADOWS 1 2 3 4 5
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04:00pm
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ENVIRONMENTAL CONSIDERATION - PROGRAMME
CIRCULATION 1 2 3 4 5 6
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PROGRAMME - KITCHEN 1 2 3 4 5 6
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PROGRAMME - DINING ROOM 1 2 3 4 5 6
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PROGRAMME - W.C 1 2 3 4 5 6
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PROGRAMME - COUNSELLING ROOMS 1 2 3 4 5 6
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PROGRAMME - LIBRARY 1 2 3 4 5 6
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PROGRAMME - LIBRARY 1 2 3 4 5 6
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PROGRAMME - PLANT ROOM 1 2 3 4 5 6
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VIEWS 1 2 3 4 5 6
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Views from with in the centre to the outside
VIEWS 1 2 3 4 5 6
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Lines of view from main entrance see into all main rooms, creates a sense of openness
VIEWS 1 2 3 4 5 6
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The location of the office allows for a good visual connection with the entrance and overview of the building, whilst avoiding any sense of formal reception or observation. It is at the same time located away from the main areas of activity to allow the staff to work without distraction when necessary.
BUILDING SECURITY 1
Plan detailing locations of vibration detectors.
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Due to the large expanses of glazing the building has sophisticated intrusion alert systems, located in every room.
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BUILDING SECURITY 1
Plan detailing locations of P.I.R sensors
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PART K - PROTECTION FROM FALLING In relation to the above Approved document the staircase down to the basement has been designed in full accordance with the regulations stipulated. All internal ramps are at a 1:20 gradient.
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PART M - ACCESS & EGRESS Plan denoting the route from the nearest setting down point to the principal entrance of the building for ambulant disabled users.
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PART M - USER COMFORT 1 2 3 4 5 6
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ACOUSTICS 1
Sound made within the spaces of the centre reverberate off the solid surfaces around the centre as there is nothing to break the sound up, voices can carry around the entire centre.
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This can be particularly problematic with concerns to confidentially in the counselling rooms
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ENVIRONMENTAL SYSTEMS - HEATING,COOLING & VENTILATION
LOCATION OF PLANT ROOM 1 2 3 4 5 6 7
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The Maggie’s centre plant room is located in the basement of building situated underneath the kitchen area
DISTRIBUTION OF SERVICES 1 2 3 4 5 6 7
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PRESUMED SURFACE WATER DRAINAGE 1 2 3 4 5 6 7
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PRESUMED FOUL WATER DRAINAGE 1 2 3 4 5 6 7
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FOUL WATER DRAINAGE MAP 1 2 3 4 5 6 7
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SURFACE WATER DRAINAGE MAPPING 1 2 3 4 5 6 7
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SURFACE WATER COLLECTION 1 2 3 4 5 6 7
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MECHANICAL EXTRACTION 1 2 3 4 5 6 7
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HEATING TRENCH LOCATION 1
The building is heated using an internal trench which sits parallel with the glazing in the building.
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Advantages include:
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Heat introduced at the lowest point and allowed to rise up naturally, heating the whole volume of the room.
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Cold air coming through the windows pushes the air as it rises using convection, radiating it naturally around the room.
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helps eliminate condensation through warming the glass itself.
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TRENCH HEATING SYSTEM 1 2 3 4 5 6
Cold air from glazing produces a downward draught
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This enters the trench through a steel grill
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Warm air is released to heat the building. Particularly efficient as it eliminates condensation when placed in front of glazing
THERMAL INSULATION 1 2 3 Due to the large amount of glazing the building suffers from heat loss, insulation has had to be over-compensated elsewhere to help combat this.
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MECHANICAL VENTILATION 1
The kitchen area has specific ventilation requirements: For example the oven and cooker produce excess heat which is taken out by an extractor fan
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warm air is extracted and circulated outside
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Maintaining temperature and humidity of room
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MECHANICAL VENTILATION 1
Spaces with particular needs - W / C始s Toilets are mechanically ventilated with an air extractor fan Maintains temperature
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ENVIRONMENTAL SYSTEMS - LIGHTING
ARTIFICIAL LIGHTING 1
Plan showing locations of all artificial lighting through out the centre.
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There are two types of lighting used:
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L.E.D strip lighting and ceiling mounted spotlights, shown below:
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NATURAL LIGHTING 1
Plan detailing the sources of natural lighting through glazing
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The scheme is configured to provide as much natural light as possible and create a sense of openness and connection throughout the building
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NATURAL LIGHTING 1
Plan detailing the sources of natural lighting through roof lights
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NATURAL LIGHTING 1
The building relies on natural lighting through large glazing systems around the structure. This gives a connection to the outside world for patients - rather than a feeling of isolation
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SUSTAINABILITY - ENVIRONMENT
REASONS FOR NATURE ON SITE 1 2 3 4 5 6 7 8 9
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A sense of the natural world that whole cycle of the change and growth and everything coming to pass, we almost forget life is a series of cycles of change you get that from the natural world, you can connect with the garden, the patient see’s the leaves come on to the trees and fall off again. Create’s a sense of permanence what i look like now will change and come back again.
TREE SURVEY 1 2 3 4 5 6
During construction a small amount of low to moderate trees were removed to facilitate the new build. As a number of trees were removed from site 120 trees of native species were planted on site as well as trees introduced to the parking areas, this further enhanced the natural surroundings. Of the new trees to be planted, it is proposed that 75% of the trees along the pathways be mature at the time of planting and 25% of the remaining trees be mature.
Before construction could take place a detailed tree survey to assess the relative health and merits of the existing trees on site was undertaken by Aspen Tree Care The ground cover consists of native species, maintained to create a natural idyllic setting for the building providing a sense of relief and escape. The following species have been found on site HAWTHORN GOAT WILLOW
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BEECH SILVER MAPLE TURKEY OAK
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EUROPEAN LIME SYCAMORE HOLLY HORSE CHESTNUT FLOWERING CHERRY
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ASH
Plan showing location and categories of each tree on site
TREE SURVEY
The site consists of predominately category B and C trees, tress that were of benefit to the environment and immediate site were sectioned off by protective fencing whilst construction on site was undertaken.
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TREE PROTECTION PLAN Root Protection Area (RPA) Protective Fencing / Construction Exclusion Zone Tree Categories on site: Category R Trees of no value to site or environment and are recommended for removal Category A Those of high quality and value: in such a condition as to be able to make a substantial contribution( a minimum of 40 years is suggested) Category B Those trees of moderate quality and value: those in such a condition as to make a significant contribution ( a minimum of 20 years is suggested )
Category C Those trees of low quality and value: currently in adequate condition to remain until new planting could be established or young trees with a stem diameter below 150 mm ( a minimum of 10 years is suggested )
SUSTAINABILITY CRITERIA 1 2 3 4 5 6 7 8 9
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CONCLUSION
CONCLUSION 1 2 3 4 5 6 7 8 9 10
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CONCLUSION 1 2 3 4 5 6 7 8 9 10
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CONCLUSION 1 2 3 4 5 6 7 8 9 10
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CONCLUSION 1 2 3 4 5 6 7 8 9 10
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CONCLUSION 1 2 3 4 5 6 7 8 9 10
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REFERENCE
REFERENCE - WEBSITES 1 2
http://www.maggiescentres.org/ http://www.designboom.com/architecture/oma-construction-for-maggies-centre-gartnavel-starts/ http://www.designboom.com/architecture/oma-maggies-gartnavel/ http://www.architectsjournal.co.uk/buildings/aj-building-studies/maggies-centre-gartnavel-hospital-glasgow-by-oma/8621394.article
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http://www.dezeen.com/2011/10/05/maggies-gartnavel-by-oma/ http://oma.eu/projects/2008/maggie-s-centre-gartnavel
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http://www.ribablogs.com/?tag=maggies-cancer-caring-centres http://openbuildings.com/buildings/maggies-centre-gartnavel-profile-3076
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http://www.architectsjournal.co.uk/news/daily-news/omas-glasgow-maggies-centre-wins-doolan-award-2012/8638392.article http://www.urbanrealm.com/news/3109/First_major_UK_exhibition_of_OMA_work_to_be_staged_at_the_Barbican.html
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http://www.worldarchitecturenews.com/index.php?fuseaction=wanappln.showbriefdetail&newsid=1747 http://www.rias.org.uk/rias/news/2012/november/maggies-gartnavel-in-glasgow-scoops-uks-richest-architecture-prize/ http://archweekpeopleandplaces.blogspot.co.uk/2012/11/maggies-centre-gartnavel-wins-2012.html http://www.archdaily.com/291823/omas-maggies-gartnavel-wins-2012-doolin-prize/ http://ribastirlingprize.architecture.com/ http://www.archello.com/en/project/maggie’s-gartnavel http://www.bdonline.co.uk/buildings/maggie’s-centre-gartnavel-by-oma/5025614.article http://www.dunne-group.com/HEADLINES/Maggie's%20Centre.html http://www.flickr.com/photos/royalincorporationofarchitectsinscotland/sets/72157631969657208/ http://www.metalocus.es/content/en/blog/maggie’s-centre-gartnavel-oma http://www.wallpaper.com/architecture/maggie146s-gartnavel-glasgow-building-by-oma/5451
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http://pdfserver3c.glasgowcitycouncil.co.uk/WAM/doc/BackGround%20Papers-185032.pdf? extension=.pdf&id=185032&location=Volume2&contentType=&pageCount=1 http://www.building.co.uk/buildings/maggie’s-centre-gartnavel-by-oma/5025614.article
REFERENCE 1 2
JOURNALS The Architects Journal - RIBA Stirling Prize 2012 - 11/10/12 - Number 13 - Volume 236 Building design - OMA's Maggie's awarded - no. 2037 - 2012 Nov. 16, p. 2.
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APPROVED DOCUMENTS BUILDING REGULATIONS - PART B BUILDING REGULATIONS - PART K BUILDING REGULATIONS - PART M VIDEO RESEARCH
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http://vimeo.com/46209501 http://vimeo.com/50512659