RIBA Stirling Prize 2021 winner
Kingston University Townhouse Project HybriDfMA Bespoke System
PCE | Willmott Dixon
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CONTENT
4 6 7 8 10 12 13 14 16 18 20 22 24 25 26 28 29 30 31 32
Introduction
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Responding to the Site
36
Project Overview
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Facade and Roofscape
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Stage Three Concept
50
Structural Concepts at Stage C
52
Concept to Reality
55
TABS System
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Stability System
60
Site Logistics
64
Building Details
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Site Location and Analysis
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Introduction to the Concept
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Links to Community
46
Architectural Influence on Structure
51
Long Span Ribbed Slab Development
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Integration of Services Within the Structure
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Vertical Structure
58
Structural Principles
62
Supply Chain Mapping
Componentised Model
Floor Plate Arrangements
Superstructure Construction Key Frame Interfaces Feature Stairs
Feature Stairs Development Atruim and Feature Stairs Auditorium
Structural Colonnade and Walkways Colonnade Cladding Interfaces Cladding Interfaces
Key Interface Development Drainage Strategy Colonnade
Colonnade Key Interfaces Colonnade Construction
Colonnade Walkway slabs Our People
Sustainable Delivery
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INTRODU
The new Townhouse Building at Kingsto in the universities broader masterplan flexible, interdisciplinary learning space community.
The conceptual design of the building is Road campus as a place of excellence whilst creating a sense of community a study at and visit the campus.
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The architect’s vision was to create a b terms of vertical and horizontal space building whose architectural integrity re to accentuate the beauty of the buildin spaces for those who use the building. building which utilises the thermal mas the internal environment whilst minimis
UCTION
on University represents a key milestone n development and its drive towards es which link the university to the wider
one which seeks to anchor the Penrhyn e for technology and performing arts and arrival and belonging for those who
building with little or no boundaries in es, and internal and external spaces. A elies on the structure and its materiality ng and to create dramatic and inspiring A robust, high quality and sustainable ss within the concrete frame to regulate sing energy usage.
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Internal spaces are linked together both horizontally vertically through atriums. Vertical Circulation is pri via feature stairs within the main full height atrium.
BUILDING DETAILS To secure planning consent, the architect designed a building which tiered from front to back to minimise the impact on the surrounding residential properties and to maximise the impact to the Penrhyn Road elevation. The building is recti-linear with a staggered rear elevation to accommodate the shape of the site. Arranged over 6 floors the new building creates over 11,000m2 of flexible interactive teaching and learning spaces. The tiering of the roofs creates usable external spaces which link to the inside. The building is wrapped on three sides by a full height structural concrete colonnade which creates external spaces, opportunities for vertical circulation, areas for plants and trees, and linkage to the pavement and subsequently the community. The colonnade serves to remove barriers between the university campus and its surrounding area and seeks to ‘open the universities doors’ to the world outside.
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y and imarily
RESPONDING TO THE SITE The Townhouse Building replaces a 1960’s prefab structure which housed a number of functions including the Student Union and the Universities archives and library. The new structure is situated on the site of the existing building and is directly adjacent to Penrhyn Road which is the main arterial route into Kingston from the south which means it is extremely busy in terms of traffic along with being part of the London red route and cycleway. The site is triangular in plan with the remaining sides directly abutting the existing university buildings and a residential street.
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The 71, 281, K2 and K3 buses all run along Penrhyn Road and there are stops directly outside the main entrance. The University has limited on-site parking facilities and prioritises staff during core working hours (Monday to Friday, 7.30am to 4.30pm).
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SITE LOCATION AND ANALYSIS
Penrhyn Road, Kingston upon Thames, Surrey KT1 2EE
Council offices directly opposite the site
Penrhyn road
Trees to remain
Neighbours adjoining the site
Bus stop Site access – one way in and out Pedestrian crossing
University building directly adjacent to the site
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PROJECT OVERVIEW 6 storey multi-use teaching and learning facility designed to link the University campus with the surrounding area. The building acts as the front door of the University, providing information and assistance, celebrating learning, showcasing achievements and supporting collaborations with industry and others. The internal spaces will provide a range of functions including: • • • • • • • •
Learning Resource Centre including quiet study Library and Archive Flexible Technology Hub Covered Courtyard designed for innovative learning and experimentation, as well as civic engagements and creative enterprise opportunities Rehearsal spaces for academic dance courses Events spaces and recording studios Cafés Public Landscaped Areas and Roof Gardens
PCE Team: Banagher Precast Techrete Oranmore Precast Peikko Shay Murtagh Precast Bravejoin Steel Fabrications
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CONTRACT VALUE GIFA CLIENT MAIN CONTRACTOR ARCHITECT PROJECT MANAGER Stages B-E Structure & Civils Stages B-E M&E Stage F M&E
£41million 11,500m2 Kingston University Willmott Dixon Grafton Architects Turner & Townsend AKT11 Chapman BDSP DES & CMB
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INTRODUC THE CO
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Grafton Architects secured the scheme of a social space which tied the Univers which sought to express itself as a mo to its surrounding areas through the u buildings around it. Conceptually it was fundamental t the architectural skeleton of all of the b remain fully exposed without any applied be designed to express the structural ar as important aspects of the architectur of finish and detailing would be required
FACADE AND ROOFSCAPE Tiering roof scape to the rear of the site allows for large usable spaces to be created such as roof gardens and café seating. The Colonnade links the new building Penrhyn Road along with providing a skeleton for vertical planting.
CTION TO ONCEPT
during a competition with their vision sity and Community together. A building odern, contemporary design but routed use of materials similar to those on the
that the concrete structure formed building’s finishes. The structure was to d coatings or coverings. The frame was to rrangements, connections and interfaces ral design. This means the highest level d.
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LINKS TO COMMUNITY The internal structure of the building provides a three-dimensional matrix, one singular complex space, which links the various required uses to one another, while at the same time giving each its own identity and privacy. Externally the highly imaginative façade is made up of an open undercroft colonnade at ground floor to invite public use and activity, above which three cascading terraces form hanging gardens giving a sense of landscape connecting from ground level to the top of the building.
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Links between internal and external spaces
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STAGE THREE CONCEPT Pre-Tender Flow Chart Decision to have visual concrete
YES
Decide required locations and extent
COSTING
Site visits to existing visual quality concrete buildings
Select benchmark projects
Define finish requirement Inc. Surface Features
Post-Tender Flow Chart Agree sample mixes with contractor and form faces
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Contractor produces small scale mock-up
MIX SELECTION
Construct full size mock-up
Accept mockup? NO
YES
Comme project w on sit
h ts e
ence works te
Insitu Topping min. 50mm Specialist contractor input
Select form face and layout
Precast Primary Beam
Select trial concrete mixes
Tender Documents
The stage 3 design essentially discounted traditional frame and slab construction and selected a ribbed slab arrangement. This was primarily driven by span:load requirements and the drive for as much exposed concrete surface as possible to assist with the heating and ventilation strategy. The frame was designed as an insitu Reinforced Concrete and the architect and engineer were debating either an insitu ribbed slab or precast hybrid. he Colonnade was primarily architectural precast concrete T columns and beams with an omnia type slab with an insitu concrete topping forming the walkways. The horizontal drainage system was to be embedded within the insitu topping with water falling back to the envelope line and then down RWP’s behind the precast mullions.
Ribbed Slab to be supported on primary beam via hidden shear connector
Precast Primary Beam
Precast Ribbed Slab
Precast Column
Precast Column
Precast Ribbed Slab
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ARCHITECTURAL INFLUENCE ON STRUCTURE: FABRIC FORMWORK Sheets of flexible, permeable fabric are held and tensioned in a system of Formwork to form the final cast shape. The design is iterative to achieve the optimum solution of both geometry and formwork design. Solution would be best suited to precast T-Beam elements and insitu frame.
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PROS • High quality surface finish and increased durability (permeable fabric membrane allows water to bleed from the mould). • Timber formwork system shown if figure 2 can be re-used. Decreasing the depth of beams for shorter spans is achieved by adjusting the fabric sag. • Curved tapered sections are possible so could taper from main span depth to a shallower depth at the end of the shorter spans • Lightweight formwork and less formwork = reduced material, transport and storage cost. CONS • Some potential finish differences may result between the use of timber formwork at the soffit and fabric of the beam. • Minimal precedence for its use on a large project, its use and viability will need to be discussed with the Contractors.
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FLAT SLAB
STRUCTURAL CONCEPTS AT STAGE C
Conventional Flat Slab arrangement would have resulted in twice the number of internal columns and would not have produced the exposed finishes the Architect wanted.
3D Model
Model with Reinforcment Typical Bay Plan
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In-Situ Concrete
VOIDED LATTICE SLAB Lattice
Precast Concrete Slab
Precast Lattice Flat Slab with void formers would have achieved the finishes but would still have resulted in twice the number of internal columns.
Distribution Steel Main Steel
3D Model
Typical Section
Model with Reinforcment
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LONG SPAN RIBBED SLAB DEVELOPMENT
Various rib profiles were investigated. Ribs varied in section, reinforced or prestressed/post-tensioned and construction methodology, ie insitu concrete or composite precast concrete (hybrid).
A ‘long span’ ribbed slab was determined to be the optimal solution for the following reasons: • • • • •
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Structural efficiency and capacity Material efficiency Internal vertical space flexibility Services integration Aesthetics
The question now was what is the optimum rib arrangement, how to achieve the ribbed soffit, detailed integration with the primary frame?
At this stage the primary frame was to be Insitu Reinforced Concrete and the ribbed slab was still to be determined.
Steel Moulds for Precast Ribs
Main issues: • Expensive mould and infrastructure set-up • Heavy ribs would need to be lifted into position • Hybrid strategy complicates the procurement process and the appointment of a specialist with the skills to construct in this way
GRP Moulds for Insitu Ribs
Main issues: • Significant temporary works • Significant on site set-up time • Major health and safety risks • Risk of damage to formwork during casting
Polystyrene Moulds for Insitu Ribs
Main issues: • Significant temporary works • Significant on site set-up time • Major health and safety risks • Risk of formwork damage during casting • Polystyrene would require extensive replacement strategy due to degradation
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CONCEPT TO REALITY Typical beam to slab interface and typical 610mm deep DT slab profile at 3.2m wide to suit a structural grid of 6.4m.
PCE solution based on standard Double Tee slabs whose widths are configured to the Kingston structural bay sizes. Precast concrete columns and beams form the primary structural frame.
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610-810-1010 ribs, subject to spans and loadings
At Stage C the design team were unsure whether the pipework would be cast within an insitu concrete slab or within the structural topping of a composite slab system.
INTEGRATION OF SERVICES WITHIN THE STRUCTURE TABS System Exclusion Zone for TABS System In-Situ Concrete
The ribbed soffit provided the opportunity to take advantage of the TABS (Thermal Activated Building) system which utilises the thermal mass of the concrete structure to cool/ condition the air within the building. Ambient water is fed through the embedded pipework to control the concrete surface temperature. This means that warm air rising within the building is then cooled to maintain a comfortable internal air temperature without the need for significant HVAC (Heating Ventilation Air Conditioning) installations.
TABS system in the in-situ concrete structural option
TABS System Exclusion Zone for TABS System In-Situ Concrete Precast Concrete TABS system in the precast concrete structural option
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TABS SYSTEM Overview
The Kingston University Estates Team required a heating and cooling solution for its new town house development, which could fulfil the following requirements: reduce energy loads, maintenance and carbon emissions. What’s more it was imperative that a longterm financial benefit could be achieved.
The town house development, which will form a key component of the University’s Penrhyn Road campus, will be completed in time for the 2019/20 academic year. The campus will also feature a flexible teaching space, cafeteria and landscaping.
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Uponor’s Involvement
Early engagement with the main contractor (Willmott Dixon) was imperative for ensuring project success. For example, Willmott Dixon initially highlighted that a minimalist design would be adopted with clean lines and open spaces. As such, there was no room for cumbersome units or voids. The beauty of Thermally Active Building Systems (TABS) is that it can be embedded (pipes) within the concrete mass of a ceiling in a discrete way, so as not to impact the overall aesthetic appeal. It provides an ambient temperature within the building by heating and cooling the water supplied with minimal energy and is linked to the outdoor climate. The TABS was installed a year ahead of the completion date and fulfilled the budget and time constraints set out.
Benefits
TABS will assist Kingston University with achieving its aim of a BREEAM ‘Excellent’ accreditation by reducing overall energy consumption. What’s more, it is highly versatile and can be adapted according to conventional and renewable energy sources, whilst also taking into consideration site dynamics. TABS only require a minimum adjustment in the water temperature of +/-4 or 5oC and works silently in the background (perfect for academic and work environments) as a “fit and forget” solution.
Uponor Contribution: TABS (9,027m2)
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VERTICAL STRUCTURE
Internal columns support gravity loads from the Superstructure and Colonnade columns support gravity loads externally.
Three stability cores provide lateral stiffness to resist wind loading and notional horizontal loading on the building.
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Plan View
CORE 1
Finite Element Model and Detected Shape
CORE 3 CORE 2
3D View
STABILITY SYSTEM Lateral deflection analysis to determine were the cores adequate to provide enough stiffness to withstand all lateral forces.
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STRUCTURAL PRINCIPLES Idealised structural principles diagram identifying load distribution through the frame structure, back to the stiff cores and down to the foundations.
Columns in the northeast corner of buildings act as fixed base cantilevers above level three to resist lateral loads in absence of a core.
Key issues: • Temporary stability • Stability Cores didn’t necessarily run full height and were disparate in terms of position • Stability for the Colonnade had to be provided by the main superstructure but the two structures needed to be independent due to thermal expansion and contraction
L6 L5
Tension compression force in slabs due to lateral forces
L4 L3 L2
Colonnade column offsets induce tension and compression in colonnade beams
L1
Main Frame
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Three cores provide majority of lateral stability
Push and pull forces from the cores act on the raft which transfers forces to soil below
Colonnade
Colonnade laterally restrained by main frame
Insitu toping of the precast slabs acts as something to transfer lateral loads to core walls
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SITE LOGISTICS Site logistics was a key challenge due to the tight site constraints along with the adjacency of the busy Penrhyn Road and the bus stops and pedestrian crossing directly outside the site.
PHASE 2 - COLONNADE
PHASE 1 - SUPERSTRUCTURE
Tower cranes positioned within the building footprint. This was the only option as the building occupies the majority of the site footprint.
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Peikko
38 Delta Beams
Techrete
593 Architectural PCC Elements
Shay Murtagh
PJ Sealants
38 PreFast core boxes
600m of mastic joint
Oranmore
231 hollowcore floor planks
Bravejoin
15 elements of off-site - pre assembled structural steel
Hanson
Banagher
1320 PCC elements
SUPPLY CHAIN MAPPING 32
Critical to the success of delivering the project was to align our supply chain partners with the ‘kit of parts’ the building was to be assembled from.
London Concrete
Kingston University PCE Head Office
Techrete Cladding Panels
Stairs Walls Delta Beams
e-
Lift Core Boxes Atruim Stair Steelwork Colonnade Columns and Beams
Colonnade Walkway Units
Techrete
Peikko Banagher
Beams
Shay Murtagh
Columns Hollowcore
Bravejoin
Banagher
Double Tees
Banagher
Oranmore
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COMPONENTISED MODEL Dance Studios Library
Roof
LEVEL 6
Roof Terrace Garden Café
LEVEL 5
Atrium Roof Terrace Garden General Learning Spaces Atrium General Learning spaces LRC
Auditorium Atrium Main Entrance
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Library Dance Studios Atrium Auditorium Atrium Main Entrance Auditorium Dance Studios Performance Space
LEVEL 4
LEVEL 3
LEVEL 2
LEVEL 1
FLOOR PLATE ARRANGEMENTS Colour coding identifies all of the different imposed loading and superimposed dead load conditions. The plans also identify the variability in floor plate vertically. Worst case loading was the roof terraces which included landscaping loads along with tree planters.
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SUPERSTRUCTURE CONSTRUCTION Level 1 Complete
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Level 2 Complete
Level 3 Complete
Level 4 Complete
Level 5 Complete
Level 6 Complete
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KEY FRAME INTERFACES Internal levels transition at roof level—tiered roof levels
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Column transfers to rear elevation with Deltabeam and hollowcore construction below
Stepped sill transfer to rear elevation: Generic colonnade interface with primary frame construction
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FEATURE STAIRS SEE DETAIL 5
x305UC 240 NTILEVER
FLIGHT 6
DETAIL 5 PLAN OF LANDING INTERNAL FEATURE STAIRS TRAYS GRID LINE 16.0m x305x305UC283 4.4m SPAN 3 TO 4.
6-
TYPICAL SUPPORT AT LANDING 9 LEVEL Scale 1:10 8 305 UC 158 7
Scale 1:10
5
FLIGHT 1
4
65x50 ANGLE CLEAT WELDED TO 100X50 PFC
5
3
2
1
564
70x6 ANGLE 250 LG 1000 LEDGER C/W 14 WIDE (TYPICAL) SLOTTED HOLE
S.F.L 9.850
FLIGHT 1
4
TYPICAL SUPPORT AT RISERS
2No 100x50 PFC
2
Main issues: 50 THK TIMBER FINISHES • Stair weight approx. 50t BY OTHERS 1 • Transportation and logistics problematic 4 THK BENT PLATE TRAY • Capacity of structure to carry8the weight • Deflections problematic • Mouldage expensive
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70x6 ANGLE 250 LG LEDGER C/W 14 WIDE 120x120 L 12 BOLTED TO WEB OF SLOTTED HOLE 305x305UC 158 DRILLED 22Ø HOLE FOR M20 BOLTS. (SEE STAIRS BASE CLEAT)
Section 7-7 Scale 1:5
DETAIL DETAIL 11 Scale 1:25
STRINGER
2No 100x50 PFC
TO PACK BELOW CHANNELS
9No EQUAL RISERS = 1523
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FABRICATOR TO DETAIL BRACKET TO SUPPORT LANDING TRAY.
25 THK CAST-IN PLATE & 25 F.F.L MATCH DRILLED10.150 8 No Ø33
100x50 PFC
TRAYS TO NTINUOUS OTH ENDS
TO PACK BELOW CHANNELS
100x50 PFC
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DATUM
SECTION 6-6 SLOTTED ANGLE Scale 1:5
120x120L12 DRILLED 22Ø T.O.S FOR M20 BOLTS. HOLES 23.659 14.434
Each of the 3 feature stairs are different.
CL 305x305UC158 STRINGER
TYPICAL LANDING DETAIL Scale 305x305UC283 1:10
305x305 UC 158
EXTERNAL FEATURE STAIRS 6 9.0mFLIGHT x 4.4m SPAN
Main issues: • Stair weight approx. 25t • Mouldage expensive • Trace heating wiring to be integrated
GHT 9 305x305UC158
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FLIGHT 8
65x50 ANGLE CLEAT WE 100X50 PFC
STAIRS BASE CLEAT ScaleT.O.C 1:10 23.325 14.100
3
TYPICAL HORSE SHOE SHIM 114 No OFF 8THK 54 No OFF 10THK Scale 1:5
H25 DOWEL BAR x 300 LONG WELDED TO BOTTOM FLANGE ON CENTRE LINE.
STRINGER A CONNECTION SHD Scale 1:20
FLIGHT 7 65x50L5 TREAD BRACKET BOLTED TO STRINGER (65 LTV) C T.O.S L 305 UC 158 19.459 14.434
DETAIL 2 DETAIL 2 Scale 1:10
CL 305 UC 158
1a
1b
2a
2b
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FEATURE STAIR
PLAN
PCE developed a composite solution for the long span feature stairs formed from a fabricated structural steel frame with integrated stair trays.
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RS DEVELOPMENT
SECTION 1-1
SECTION 2-2
Structural System
Structural Behaviour
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ATRIUM AND FEATURE STAIRS Vertical circulation through the structure is primarily via a full height atrium at the front elevation of the building which has three large feature stairs spanning the length of the atrium between floor levels. A composite solution was developed for the feature stairs as spans were up to 15.0m long by 4.4m high. The solution combined a fabricated structural steel frame with integrated stair trays. The soffit of the frame was clad in precast concrete panels to give the appearance of concrete and the stair trays were cast on site to keep the weight of the frame to a minimum.
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AUDITORIUM Precast Concrete Fin Columns to replicate external Fin Columns
Precast Concrete Raker Beams on Precast Concrete Columns
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Precast Concrete Terrace Seating with encast circular holes for ventilation
Precast Concrete Stair Flights
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STRUCTURAL COLONNADE AND WALKWAYS
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Colonnade structure is independent from the Superstructure for movement but retains lateral stability from the main stability structure.
Joint on Colonnade Centerline
Longitudinal Edge Beam
Mullion
Support for Stairs Slab
Drainage Channel Column Planter Structure
COLONNADE CLADDING INTERFACES Extract from the Colonnade above the main entrance to the building. The details show the close interaction between the Colonnade structure, the glazing and façade/envelope finishes and the internal structure.
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CLADDING INTERFACES
Mullion connections on the building facade
Internal Panels Framing System External Pre-Cast Ribs
Internal Pre-Cast Ribs Primary Pre-Cast Column
External Brickwork Panels
Glazing
Primary Pre-Cast Beam Ribbed Slab
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The details show the close interaction between the Colonnade structure, the glazing and façade/envelope finishes and the internal structure. The visuals also give a feel for how the external planting will work with the Colonnade structure.
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KEY INTERFACE DEVELOPMENT
Encast RWP transition through beam and walkway slab interface
Integration of drainage within the Colonnade and key connection interfaces.
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Drainage transition across tie beams to encast RWP within columns
Drainage transition from planter to vertical RWP within columns
Structural connections and interfaces between key Colonnade elements
Support details from Colonnade beams from primary frame elements
DRAINAGE STRATEGY Rainwater pipes to be concealed behind the main column positions and connects at each level to horizontal drainage channels
Drainage from the planters via a horizontal drainage pipe within the tie beams
Rainwater pipes to drain the roof cast within the colonnade columns
Drainage channel within the colonnade slab takes rainwater back to the column positions
Drainage slope from rainwater and planter drainage back to the glazing line
Horizontal drainage within an integrated channel within the walkway slabs
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COLONNADE Architectural Concrete Colonnade wraps three elevations of the building.
Colonnade Walkway Slabs
Colonnade Stairs
Colonnade Roof Slabs
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Colonnade Columns
COLONNADE KEY INTERFACES
Drainage Channels
Colonnade Beam Support
Embedded Drainage
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COLONNADE CONSTRUCTION Construction of the colonnade was a significant challenge due to the complexity of the embedded services strategy, difficulties in accessibility and the temporary stability requirements. The colonnade is manufactured from a high-quality architectural finish concrete with all surfaces exposed except for those concealed by adjoining elements and structure. The temporary restraint of elements had to be discreet in terms of how struts and props connected to the elements and in most instances, stabilisation had to come from the previously constructed colonnade structure. Careful sequencing combined with a design solution heavily influenced by the assembly methodology and PCE’s ‘inhouse’ construction expertise made the delivery of the colonnade possible.
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COLONNADE WALKWAY SLABS
Glazing
Column
Drainage Slope Mullion Longitudinal Edge Beam
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Planter Structure Stairs
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OUR PEOPLE From the Project launch seminar, at which the University of Kingston and Grafton Architects set out and explained their visions for Townhouse, it was clearly apparent that the only way the Project could be a success was through a collaborative approach to every facet. One team, one Project, one shared goal - “To create a heart for the University of Kingston”. Through Design, PCE’s internal team of Engineers and Structural Technicians were driven to maintain the architectural aspects of the building rather than opting for simpler alternative structural approaches. The integration of drainage and cast-in mechanical and electrical requirements were incorporated without compromise of the vision.
The Manufacture was well controlled through PCE’s supply chain partners with quality at the forefront of every decision that was taken in how to produce the various elements. Assembly was completed by an average number of 15 of PCE’s multi-skilled operatives who worked through all weathers whilst maintaining safety and quality in every task undertaken to achieve close to 50,000-man hours with no reportable incidents. The logistically challenging site and location was well-ordered throughout with an excellent understanding and mutual respect between the construction teams of all members of the Project team.
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SUSTAINABLE
From concept through to delivery and life cycle, exemplar demonstration of how the fabric of the the carbon footprint of the Construction process replacements. Sustainability calculations followi over 85% of structural components delivered, th
Professor Steven Spier, Vice Chancellor of Kingston University commented: “World-class architecture isn’t just the preserve of the Russell Group! I’m delighted that with Town House, everyone who visits, studies in, and works at Kingston University now has access to a beautiful and inviting space in which to learn, socialise and just be.”
Roger Forsdyke, Managing Director of Willmott Dixon in London & South has stated that: 64
“Town House was a hugely ambitious project – one we fully embraced. Although it was complex and highly challenging at times, it’s testament to the team’s dedication that the original design has been realised to such exacting standards.”
DELIVERY
a sustainable solution was fundamentally at the heart of the Universities vision. The Townhouse is an e building can be used throughout the life cycle of the building to minimise carbon emissions. In addition, s was significantly reduced through the use of a DfMA strategy combined with extensive use of cement ing project completion show that for offsite manufactured precast concrete units, which accounted for he CO² footprint was less than 230kg/m² for the total building floor area.
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RIBA STIRLING PRIZE W
This is a great achievement and we congratulate Grafton Architects on w Award for their architecturally brilliant design.
Working with Grafton Architects, Willmot Dixon Construction and AKT I very proud of our contribution to this impressive building in taking wha construction design and enabling an offsite engineered Design for Manu (DfMA) solution to provide the stunning architectural functionality and requirements and high quality concrete finishes required.
The skill and knowledge of our in house multi-disciplinary site team ena the superstructure to ensure the highest level of quality concerning accu achieved with full regard to all Health and Safety and Environmental con ensuring minimal disturbance to the University on what was a restricted
PCE’s HybriDfMA Bespoke System solution enabled an architecturally co and facade to be economically achieved by an Offsite and Modern Metho approach.
Grafton Architects:
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“The buildings external expression seeks to incorporate a visuall articulation and detailing, with an emphasis on assembly of mate is finely detailed and robust, ensuring the longevity of the quality of the building. The interior of the building is predominantly defi beam structural system supporting exposed concrete ribbed slab quality and character of the spaces within and are influenced by of finish of the concrete. Our collaborative working relationship w the design and offsite manufacturing process was a rewarding ex subsequent careful assembly of the building’s concrete elements building’s three-dimensional structural matrix and envelope con success of the project. It was a genuine pleasure to work with you we’ll cross paths again on another project somewhere”.
WINNER
winning this significant
II, we at PCE Ltd are at was an initial onsite ufacture and Assembly, appearance, structural
abled assembly of uracy and fit and was nsiderations as well d site.
omplex structure ods of Construction
ly rich façade in terms of erials in a manner which y of the appearance ined by a column and bs, that defines the the type and quality with PCE throughout xperience, and the s on site to form the ntributed to the overall u guys and hopefully
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