Whitman School of Management Analysis and Intervention

Page 1

PROJECT OVERVIEW

ARCHITECTURAL DESIGN

BUILDING AND SITE

STRUCTURAL SYSTEMS

MECHAN ICAL SYSTEMS

PLUMBING SYSTEMS

ELECTRICAL SYSTEMS

FACADE + ROOFING

d an Sc alkyar e c n itm ston H a v Wh We Ad

abe H avid

s m m D e e t g rd / s a a y y n g S Ma r Halk in ol of anne d l i Bu ho d/T

Rh n/ rma

ent

uno Br ett


ARCHITECTURAL DESIGN

Plumbing Systems

Project Overview 2

12/5/11

General Overview

52 53

Sewage Conditions/ Drainage Fire Suppression

Architectural Design Program Circulation Atrium Classrooms Office/ Meeting Rooms Spine

55 56 57

Lighting/ Classrooms Lighting/ Office Block Lighting/ Spine

Facade and Roofing Systems Location Context Traffic Wind Temperature Sunlight Louvres

59-60 62 63-64 65

Facades on Plans Atrium Roofing Materiality Occupancy Control

MECHAN ICAL SYSTEMS

14 15-17 18 19 20 21-25 26

Electrical Systems

STRUCTURAL SYSTEMS

Building and Site

BUILDING AND SITE

4-5 6-7 8 9 10-11 12

Matrix Structural Systems Framing Structure Atrium Structure Metal Panel Facade Brick Facade Glass Facade

Table of Contents

68-73

Thermal Massing Wall and Louvres & Adjustable Office Windows

74-81 82-96

Green Roof Atrium Natural Ventilation Break

HVAC in Atrium HVAC in Classroom Block HVAC in Office Block HVAC in Spine

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

40-41 42-44 45-47 48-50

Interventions

ELECTRICAL SYSTEMS

Mechanical Systems

Matrix

PLUMBING SYSTEMS

28-30 31-35 36 37 38

66-67

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT


PROJECT OVERVIEW

PROJECT OVERVIEW

ARCHITECTURAL DESIGN

BUILDING AND SITE

STRUCTURAL SYSTEMS

MECHAN ICAL SYSTEMS

PLUMBING SYSTEMS

ELECTRICAL SYSTEMS

FACADE + ROOFING


12/5/11

GENERAL OVERVIEW:

ARCHITECTURAL DESIGN

SIZE: 165,000 square ft

BUILDING AND SITE

PROGRAM: Classrooms, Auditoria, Space for team meetings and collaborative activityExecutive Learning Space, Bathrooms, Lounge

STRUCTURAL SYSTEMS

PRIMARY DESIGN ELEMENT: Central communication circulation corridor with a grand stair maximizes program connectivity and daylight penetration of all the interior spaces. It integrates sustainable systems including a sophisticated building management system, under-floor air distribution, and radiant heating and cooling.

MECHAN ICAL SYSTEMS PLUMBING SYSTEMS

PROGRAM TYPE: College/ University CAPACITY: 1,270 people

ELECTRICAL SYSTEMS

BUILDING COST: $30,000,000 COST PSF: $187

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

DESIGNER : FXFOWLE Architects

General Overview

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT


PROJECT OVERVIEW

ARCHITECTURAL DESIGN

ARCHITECTURAL DESIGN

BUILDING AND SITE

STRUCTURAL SYSTEMS

MECHAN ICAL SYSTEMS

PLUMBING SYSTEMS

ELECTRICAL SYSTEMS

FACADE + ROOFING


12/5/11

Classrooms Offices Bathrooms

BUILDING AND SITE

Vertical Circulation Communal Space

STRUCTURAL SYSTEMS

Each of the primary curriculum programs Undergraduate, Graduate and Executive occupies its own floor in the building. This includes administrative offices, student activity and breakout rooms, and classrooms. Common functions, such as the cafeteria and special teaching spaces, are interspersed on these floors to assure a degree of interaction between students of different programs. The faculty offices and support facilities clustered in the taller, masonry volume on the top two floors, provide calmness away from major activity and ensures camaraderie and communication between academic departments, while remaining accessible to students. The concourse and first floor levels provide spaces for reception andother common uses as well as classrooms shared with the University as a whole.

ARCHITECTURAL DESIGN

PROGRAMMATIC CONCEPT:

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

MECHAN ICAL SYSTEMS PLUMBING SYSTEMS

The building includes: - 22 classrooms - 200-seat auditorium - 20 team meeting rooms / undergraduate and graduate computer clusters - 11 centers and institutes - 12 student clubs and organizations - Career Center - The Lubin Visitor’s Center

ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Program


12/5/11

Bathrooms

Auditorium

Milton Hall

Offices

Atrium

Cafe

Mechanical

ARCHITECTURAL DESIGN

Classrooms

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

BUILDING AND SITE STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS

Horizontal circulation Vertical Circulation

PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Program


12/5/11

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

ARCHITECTURAL DESIGN

Horizontal Circulation

BUILDING AND SITE

Cir c

STRUCTURAL SYSTEMS

ula tio

n

Vertical Circulation

MECHAN ICAL SYSTEMS PLUMBING SYSTEMS

Elevator Core

ELECTRICAL SYSTEMS

Circulation

Advanced Building Systems

Office/ Meeting Rooms

Weston Halkyard

Tanner Halkyard

Atrium

Rhett Bruno

David Haberman

FACADE + ROOFING

Classrooms


12/5/11

East Adams St.

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

ARCHITECTURAL DESIGN PLUMBING SYSTEMS

Walnut Pl.

MECHAN ICAL SYSTEMS

‘Spine’

STRUCTURAL SYSTEMS

University Ave.

BUILDING AND SITE

- The Spine Draws in pedestrians from each of the surrounding streets and then acts as an interior street on which Whiman’s new ‘Urban Fabric’ is located. It is in the spine that all major circulation takes places, connecting the many programs.

ELECTRICAL SYSTEMS

Circulation

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Marshall St.


12/5/11

ARCHITECTURAL DESIGN

ATRIUM/ COMMUNITY LEVEL SPACE

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

BUILDING AND SITE

The Atrium is designed to extrude from the urban fabric and and engage both the path of the campus and the street. Aglow with natural light and adorned with interior trees, the atrium provides an ideal lounge/study/special event area with a strong sense of place. At night, the atrium’s transparency opens the building to the exterior, offering dramatic views of the campus and downtown.

STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

L OF MANAGEMENT MARTIN J. WHITMAN SCHOO

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Atrium


12/5/11

ARCHITECTURAL DESIGN

ClASSROOM BLOCKS

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

BUILDING AND SITE

The finishes of the classrooms balance a dignified corporate ambience and a free-spirited student learning environment. They are set within a case of metal and glass, more public then the office block, but less then the atrium. The glass allows diffuse light into the space, ensuring a suitable teaching space, as well as dimmable artificial lighting.

STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Classrooms


12/5/11

ARCHITECTURAL DESIGN

OFFICE/ MEETING ROOM BLOCKS

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

BUILDING AND SITE

Expressing the essence of the building’s function, the classrooms are clustered in a volume as a “machine for teaching.” Encased in brick, this is the most private of the block within Whitman’s urban fabric. Where on the first floor it counters the very public atrium by privatizing entirely, on the second a cafe interacts with the the same space. Up until the Atrium roof the floors are mixed between public meeting rooms and private offices, distinguishing between them by either clear or glazed glass.

STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Office/Meeting Rooms


12/5/11

MECHANICAL SYSTEM PLACEMENT: PUBLIC vs. PRIVATE

ARCHITECTURAL DESIGN

Private Offices Public Meeting Rooms

- With mechanical and service systems located in the basement and the penthouse, public and private spaces filter in between. Sandwiched between the first and sixth floor which are completely private, are a mix of spaces where privacy prevails as height reaches above the atrium.

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Mechanical/Service

BUILDING AND SITE STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Office/Meeting Rooms


12/5/11

ARCHITECTURAL DESIGN

CIRCULATION SPINE

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

BUILDING AND SITE

The circulation spine unifies the composition of Whitman, bringing clarity and orientation to the occupants and, through its diaphanous façade, animating the building both day and night. Sliding out from the other volumes light is able to diffuse through the glass and connect each space. With its shiny metallic ceiling and sparkling terrazzo floor it is meant to remain as bright as possible.

STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

‘Spine’


PROJECT OVERVIEW

ARCHITECTURAL DESIGN

BUILDING AND SITE

BUILDING AND SITE

STRUCTURAL SYSTEMS

MECHAN ICAL SYSTEMS

PLUMBING SYSTEMS

ELECTRICAL SYSTEMS

FACADE + ROOFING


12/5/11

GEOGRAPHIC LOCATIOIN

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

ARCHITECTURAL DESIGN BUILDING AND SITE STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Site Conditions | Location


12/5/11

Drag direction of green across the block

STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS

Low scale structures

BUILDING AND SITE

Parking

The exterior uses natural grass in areas where maple and birch trees are planted, however also incorporates a special type of grass to elaborate on the greenery. Bahia grass occupies the south west side of the building near the the corner and the Sheraton. This type of grass can withstand high heat temperatures as occur in the summer and low temperatures that occur during the winter.

ARCHITECTURAL DESIGN

Green Connection

The green space that is Walnut park just across the block is the perfect place to draw from in terms of connecting the environment to the Whitman site which is otherwise made up of streetsides and pavement. The site takes the vegetation from the park and incorporates them not only in the direct vicinity of Whitman, but also pulls them directly into the interior courtyard space.

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

PLUMBING SYSTEMS

Sheraton N

ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Site Conditions | Context


12/5/11

N

MECHAN ICAL SYSTEMS

Gateway Directinality

Gateway

Sheraton

STRUCTURAL SYSTEMS

Low scale structures

BUILDING AND SITE

Whitman is placed on one of the most important lots within the urban layout and occupies the corner of University ave (a primary vehicle occupancy street) and Marshall St ( a primarily pedestrian occupied street.)

ARCHITECTURAL DESIGN

Parking

Whitman School of Management is located on the center axis of the urban grid for the Marshall street area of the University, It occupies the righthand corner of the campus’ “gateway” and draws one through with a finale view of the Hall of Languages directly up university ave. the angle of the fenestrated lounge area of Whitman opens up the building to the occupancy of the street as well as the view towards the entrance as you move up towards the Sheraton.

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Center Grid Line

PLUMBING SYSTEMS

Center axis cross points

ELECTRICAL SYSTEMS

Site Conditions | Context

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Hall of Languages


12/5/11

Service

BUILDING AND SITE

Parking

Site

The Glass atrium area of Whitman faces the sun as well as the university. the view towards the Hall of Languages is unobstructed from the corner ofthe lounge. The glass provides not only a window like view but is classified as an outdoor spaces, so the sheer size of the “wall” allows for a complete scenic view.

ARCHITECTURAL DESIGN

View towards the University

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

STRUCTURAL SYSTEMS

Low scale structures

MECHAN ICAL SYSTEMS

Sheraton N

PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Site Conditions | Context


12/5/11

East Adams St.

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

ARCHITECTURAL DESIGN BUILDING AND SITE

Walnut Pl.

MECHAN ICAL SYSTEMS

University Ave.

STRUCTURAL SYSTEMS

Paving Connection showing how the Design of Whitman connects with the paving directioinality of the directly surrounding area.

PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Site Conditions | Traffic

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Marshall St.


January

Febuary

9/15/11

March

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

ARCHITECTURAL DESIGN BUILDING AND SITE

May

April

June

STRUCTURAL SYSTEMS

August

Sepember

MECHAN ICAL SYSTEMS

July

PLUMBING SYSTEMS

Average Wind Speed- Syracuse 30 mph 25 mph

October

November

December

20 mph

ELECTRICAL SYSTEMS

15 mph 10 mph 5 mph

JAN FEB

MAR APR MAY

JUN JUL AUG SEP OCT NOV DEC

Site Conditions | Wind

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Maximum Average


12/5/11

ARCHITECTURAL DESIGN

Average Temperatures °F

Average Relative Humidity % 100%

90°

90%

80°

80%

BUILDING AND SITE

100°

82°

61°

69%

70%

60°

56%

60% 50%

40°

40%

30°

30%

20°

20%

10°

10%

JAN

FEB

MAR APR

MAY

JUN

JUL

AUG

SEP

OCT

NOV

DEC

JAN

FEB

MAR APR

MAY

Morning

Low

Afternoon

JUL

AUG

SEP

OCT

NOV

DEC

PLUMBING SYSTEMS

High

JUN

MECHAN ICAL SYSTEMS

50°

STRUCTURAL SYSTEMS

70°

ELECTRICAL SYSTEMS

22 degrees = winter ave. 82 degrees = summer ave.

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Site Conditions I Temperature

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT


12/5/11

MECHAN ICAL SYSTEMS

Average Percentage of Sunshine 100%

Sh

er

at

90%

on

80%

PLUMBING SYSTEMS

70% 60% 50% 40%

20% 10%

N JAN

FEB

MAR APR

MAY

JUN

JUL

AUG

SEP

OCT

NOV

DEC

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

South

ELECTRICAL SYSTEMS

30%

Site Conditions | Sunlight

STRUCTURAL SYSTEMS

The exterior uses natural grass in areas where maple and birch trees are planted, however also incorporates a special type of grass to elaborate on the greenery. Bahia grass occupies the south west side of the building near the the corner and the Sheraton. This type of grass can withstand high heat temperatures as occur in the summer and low temperatures that occur during the winter.

BUILDING AND SITE

Site

ARCHITECTURAL DESIGN

Sunlight Exposure

The green space that is Walnut park just across the block is the perfect place to draw from in terms of connecting the environment to the Whitman site which is otherwise made up of streetsides and pavement. The site takes the vegetation from the park and incorporates them not only in the direct vicinity of Whitman, but also pulls them directly into the interior courtyard space.

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT


12/5/11

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

ARCHITECTURAL DESIGN BUILDING AND SITE STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Site Conditions | Sunlight


12/5/11

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

ARCHITECTURAL DESIGN BUILDING AND SITE

10°

:47 20

20° 30°

:20 19

20:47

40° 5:25

50°

STRUCTURAL SYSTEMS

°

50

19:19

°

80

°

70

°

60

80°

°

40

°

30

°

20

°

10

N

:30

16

60° 70°

6:42

16:33

7:33

ELECTRICAL SYSTEMS

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Advanced Building Systems

PLUMBING SYSTEMS

The angled glass facade of the atrium allows for the maximum exposure to the sun on a daily occurance.

Site Conditions | Sunlight

MECHAN ICAL SYSTEMS

0

5:3

5

6:4

0

7:3

9 am Noon 3 pm 6 pm Sunrise/Sunset December 21 Equinoxes June 21

9 am Noon 3 pm 6 pm Sunrise/Sunset December 21 Equinoxes June 21


12/5/11

ARCHITECTURAL DESIGN

Noon Sun Intensity Sunrise/ Sunset Intensity

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

BUILDING AND SITE STRUCTURAL SYSTEMS

SUNSET SUNRISE

MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Site Conditions | Sunlight


12/5/11

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

ARCHITECTURAL DESIGN BUILDING AND SITE STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS

- Lights floods into either end of the protruding ‘spine’. The Atrium also filters light into the buildings center where it diffuses into all of its spaces.

PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Site Conditions | Sunlight


12/5/11 9/15/11

ARCHITECTURAL DESIGN

Summer Sun

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

12:00 pm

BUILDING AND SITE STRUCTURAL SYSTEMS

Winter Sun 12:00 pm

MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Louvres


PROJECT OVERVIEW

ARCHITECTURAL DESIGN

BUILDING AND SITE

STRUCTURAL SYSTEMS

STRUCTURAL SYSTEMS

MECHAN ICAL SYSTEMS

PLUMBING SYSTEMS

ELECTRICAL SYSTEMS

FACADE + ROOFING


12/5/11

ARCHITECTURAL DESIGN

FOUNDATION AND STRUCTURAL PLANS

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

BUILDING AND SITE STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS

Plan of Structural Steel Frame

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Framing Structure

ELECTRICAL SYSTEMS

Foundation and Footing Plan


12/5/11

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

ARCHITECTURAL DESIGN BUILDING AND SITE STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS FACADE + ROOFING

Framing Structure

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman


12/5/11

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

ARCHITECTURAL DESIGN

BUILDING STRUCTURE - For all the volumes but the Atrium Whitman has a simple Steel frame structure despite its differing facades that helps unify the entire construct.

BUILDING AND SITE STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Framing Structure

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Section though Foundation


12/5/11

ATRIUM STRUCTURE

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

ARCHITECTURAL DESIGN

The structure of the atrium was design for maximum light penetration. The many thin columns oriented along the interior of the glass allow for complete transparency for the campus. As the median between exterior and interior it is the most public space of the building and suggests community and interaction between the campus students and faculty.

BUILDING AND SITE STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Atrium Structure


12/5/11

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

ARCHITECTURAL DESIGN BUILDING AND SITE STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS

The steel colums in the atrium are connected to the floor through concrete and pin joint connections implying a unique structural design for the most celebrated part of the building

PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Atrium Structure

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Rotation and flexability of structure


12/5/11

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

ARCHITECTURAL DESIGN

The overhead structure of the atrium is connected by pin joints enabling a sound support to an otherwise irregular shape

BUILDING AND SITE STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Atrium Structure


12/5/11

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

ARCHITECTURAL DESIGN BUILDING AND SITE

Aesthetic wood panelling masks the systems within the atrium

STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Atrium Structure


12/5/11

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

ARCHITECTURAL DESIGN BUILDING AND SITE STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Atrium Structure

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Aesthetic wood panelling is attached to concrete slab above with steel fiber cabeling


12/5/11

CLASSROOM BLOCK STRUCTURE

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

ARCHITECTURAL DESIGN

Aluminum Composite Wall Panel

5/8” Exterior Sheathing BUILDING AND SITE

6” Metal Stud Framing

6” Foil Faced Batt Insulation STRUCTURAL SYSTEMS

Access Flooring

Concrete Slab on Metal Deck

MECHAN ICAL SYSTEMS

Continuous Metal Angle Firestops and Smoke Seals

PLUMBING SYSTEMS

Wall Section Metal Stud Bracing

ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Metal Panel Facade


OFFICE/ MEETING ROOM STRUCTURE

12/5/11

ARCHITECTURAL DESIGN

Aluminum Window Assembly

Solid Face Brick Below Horizontal Reveal 2 1/4” x 3 5/8” x 11 5/8” Face Brick 2 ” Cavity Insulation

BUILDING AND SITE

Vapor Retarder Applied to CMU Within Cavity Wall Section

6” Concrete Masonry Unit

STRUCTURAL SYSTEMS

Sprayed-On Fireproofing at Beams (2 Hr. Rating)

MECHAN ICAL SYSTEMS

Adjustable Galv. Wire Tie at Beam @ 16” O.C.

Steel Beam

Galv. Stl, Ties w/ Seismic Clip and Cont. 9 GA. Wire

PLUMBING SYSTEMS

Adhered Flexible Threu-Wall/Sill Flashing

ELECTRICAL SYSTEMS

Plastic Fiber Mesh Cavity Filler “Mortar Net”

5/8” Gypsum Board

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Brick Facade

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT


12/5/11

Concrete Floor Slab

ARCHITECTURAL DESIGN

CIRCULATION SPINE STRUCTURE

PTD. 2 Hr. Rated Shaft Wall Assemble

BUILDING AND SITE

PTD. GWB Cove

STRUCTURAL SYSTEMS

Suspended Ceiling System Anchored to Slab Above

MECHAN ICAL SYSTEMS

Wall Section

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Line of Reveals Beyond

2 Hr. Fire Rated Metal Mullion W/ PTD. Finish 2 Hr. Fire Rated Glass Wall Assembly

PLUMBING SYSTEMS ELECTRICAL SYSTEMS

5/8” Terrazzo Base Applied to 4” Concrete Block Epoxy Terrazzo Finish Floor

Glass Facade

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Concrete Floor Slab


PROJECT OVERVIEW

ARCHITECTURAL DESIGN

BUILDING AND SITE

STRUCTURAL SYSTEMS

MECHAN ICAL SYSTEMS

MECHANICAL SYSTEMS

PLUMBING SYSTEMS

ELECTRICAL SYSTEMS

FACADE + ROOFING


12/5/11

ARCHITECTURAL DESIGN

DISPLACEMENT VENTILATION AIR CONDITIONING (UNDER FLOOR)

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

BUILDING AND SITE

- A typical displacement ventilation system, such as one in an office space, supplies conditioned cool air from an air handling unit (AHU) through a low induction diffuser. The cool air spreads through the floor of the space and then rises as the air warms due to heat exchange with heat sources in the space (occupants, computers, lights). - The warmer air has a lower density than the cool air, and thus creates upward convective flows known as thermal plumes. The warm air then exits the zone at the ceiling height of the room.

STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

HVAC in Atrium


12/5/11

ARCHITECTURAL DESIGN

Voids cut in the roof allow heated air to exit naturally. The Atrium Space Can very nearly be considered an outdoor space.

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

BUILDING AND SITE STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

HVAC in Atrium


12/5/11

DISPLACEMENT VENTILATION AIR CONDITIONING (UNDER FLOOR)

ARCHITECTURAL DESIGN

Floor Vent

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Ceiling Strip Vent

BUILDING AND SITE

- A typical displacement ventilation system, such as one in an office space, supplies conditioned cool air from an air handling unit (AHU) through a low induction diffuser. The cool air spreads through the floor of the space and then rises as the air warms due to heat exchange with heat sources in the space (occupants, computers, lights).

STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

HVAC in Classroom Block


12/5/11

ARCHITECTURAL DESIGN

DISPLACEMENT VENTILATION AIR CONDITIONING (UNDER FLOOR)

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

- The warmer air has a lower density than the cool air, and thus creates upward convective flows known as thermal plumes. The warm air then exits the zone at the ceiling height of the room.

BUILDING AND SITE STRUCTURAL SYSTEMS

Strip vent warm warm air exits

MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

HVAC in Classroom Block

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Floor vents fed by low induction diffuser


12/5/11

ARCHITECTURAL DESIGN

Indicated in blue a large stack vent runs up the outside edge of both classroom volumes. Mechanical rooms hugging this “tube” help feed this displacement ventilation system.

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

BUILDING AND SITE STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

HVAC in Classroom Block


12/5/11

ARCHITECTURAL DESIGN

HVAC IN OFFICE BLOCK

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

The Office Block uses a simple radiator system along the windows where a sophsticated building monitor system is located.

BUILDING AND SITE STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

HVAC in Office Block

Supply Diffuser

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Exterior Wall Radiator


12/5/11 Supply Diffuser

Return/ Exhaust Register

Convective Radiators

ARCHITECTURAL DESIGN

Supply Diffusers allows for a split in the air flow emerging from the air duct into individual jets and guides them in the desired directions. This results in a rapid reduction in the velocity and temperature of the air entering the room, thus ensuring pleasant temperatures in the occupied zone.

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Supply Diffuser

BUILDING AND SITE STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS

Exterior Wall Radiator

PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

HVAC in Office Block


9/15/11

ARCHITECTURAL DESIGN

The entire System runs up the core where it is supplied by the mechanical room in the penthouse.

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

BUILDING AND SITE STRUCTURAL SYSTEMS

Detail of a duct when attached to the concrete slab.

MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

HVAC in Office Block

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Detail of a duct when attached to the steel frame structure.


12/5/11

ARCHITECTURAL DESIGN

On the fourth floor where there is only a glass wall, a radiotor (As seen on right) runs along the hallway opposite the vents to ensure the space is kept warm.

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

BUILDING AND SITE STRUCTURAL SYSTEMS

Radiator strip along glass wall

MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

HVAC in Spine

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Strip vents hidden along edge of wall


12/5/11

SUPPLY AND RETURN SYSTEM THROUGH THE BUILDING “SPINE”

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

ARCHITECTURAL DESIGN

Strip Vents run along the spine, with ducts breaking off to feed the public bathrooms flanking the space. The system is served by the penthouse on the 7th floor.

BUILDING AND SITE STRUCTURAL SYSTEMS

Strip vents

MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

HVAC in Spine


12/5/11

ARCHITECTURAL DESIGN

Core rises up to the penhouse to feed the system. On the fourth floor the radiator is shown where the wall becomes entirely glass along the corridor.

Mechanical Room in Penthouse

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

BUILDING AND SITE

Hvac System moves through core

STRUCTURAL SYSTEMS

Strip Vent

MECHAN ICAL SYSTEMS

Radiator along glass

PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

HVAC in Spine


PROJECT OVERVIEW

ARCHITECTURAL DESIGN

BUILDING AND SITE

STRUCTURAL SYSTEMS

MECHAN ICAL SYSTEMS

PLUMBING SYSTEMS

PLUMBING SYSTEMS

ELECTRICAL SYSTEMS

FACADE + ROOFING


Type A Grate Access Cover at Grade CB-9 Drainage

BUILDING AND SITE

Type B Grate

ARCHITECTURAL DESIGN

N

12/5/11

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Site Water Flow

Topography

STRUCTURAL SYSTEMS

Subgrade Piping

MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Sewage Conditions/ Drainage


12/5/11

FM-200 Fire Suppression Systems

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

ARCHITECTURAL DESIGN

Developed as a Halon replacement, FM-200 is the best people-compatible, clean agent fire protection for vital facilities. It extinguishes fire via a combination of chemically-based fire inhibition and cooling. It is environmentally acceptable, safe to use with sensitive equipment, fast acting, efficient and effective.

BUILDING AND SITE

FM-200 is the preferred fire suppression system for facilities that can't afford fire related business interruption. It is non-toxic on people.

STRUCTURAL SYSTEMS

Benefits of Using FM-200 • Fast-Acting FM-200 can stop fires in just seconds. Extinguishing fires quickly means less damage, repair costs and extra safety. • Safe For People FM-200 has been tested extensively to ensure safe exposure to people. • No Collateral Damage FM-200 does not leave oily residues, particulates, water, or corrosive material. This eliminates collateral damage to delicate equipment. • Environmentally Responsible FM-200 has a low environmental impact because it has a low atmospheric lifetime. It also has zero potential to deplete the ozone layer. • Small Space Requirement Other fire suppression systems, such as C02 and inert gases require as much as seven times more storage space. • Globally Accepted FM-200 is the most widely accepted clean agent in the world. It is used in tens of thousands of fire suppression systems.

MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Fire Suppression


PROJECT OVERVIEW

ARCHITECTURAL DESIGN

BUILDING AND SITE

STRUCTURAL SYSTEMS

MECHAN ICAL SYSTEMS

PLUMBING SYSTEMS

ELECTRICAL SYSTEMS

ELECTRICAL SYSTEMS

FACADE + ROOFING


12/5/11

REFLECTED CEILING PLAN: CLASSROOMS Recessed Downlight

Round Pendant

Recessed Downlight

6’ Linear Pendant

8’ Linear Pendant

Smoke Detector

ARCHITECTURAL DESIGN

Round Pendant

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

BUILDING AND SITE STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Lighting/ Classrooms


12/5/11

Recessed Downlight

Recessed Downlight

Track Lighting

8’ Linear Pendant

6’ Linear Pendant

Smoke Detector

ARCHITECTURAL DESIGN

REFLECTED CEILING PLAN: OFFICES

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

BUILDING AND SITE STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Lighting/ Office Block


12/5/11

REFLECTED CEILING PLAN: SPINE Recessed Downlight

4”x4’ Semi-Recessed Ceiling Fixture

12’ Linear Pendant

ARCHITECTURAL DESIGN

Round Pendant

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Smoke Detector

BUILDING AND SITE STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Lighting/ Spine


PROJECT OVERVIEW

ARCHITECTURAL DESIGN

BUILDING AND SITE

STRUCTURAL SYSTEMS

MECHAN ICAL SYSTEMS

PLUMBING SYSTEMS

ELECTRICAL SYSTEMS

FACADE + ROOFING

FACADE AND ROOFING SYSTEMS


12/5/11

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

ARCHITECTURAL DESIGN

View From Southeast

BUILDING AND SITE STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Facades on Plans


12/5/11

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

ARCHITECTURAL DESIGN

View From Northwest

BUILDING AND SITE STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Facades on Plans


12/5/11

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

ARCHITECTURAL DESIGN

HIGH-ALBEDO ROOFING High-albedo roof coatings can reduce building air-conditioning energy use. High-albedo--that is, very reflective--coatings lower the absorption of solar energy, reduce surface temperatures, and decrease heat transfer into the building.

BUILDING AND SITE STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Atrium Roofing


12/5/11

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

ARCHITECTURAL DESIGN

TRANSLUCENT CERAMIC FRIT

BUILDING AND SITE

- Ceramic enamel frits contain finely ground glass mixed with inorganic pigments to produce a desired color. The coated glass is then heated to about 1,150°F, fusing the frit to the glass surface, which produces a ceramic coating almost as hard and tough as the glass itself. A fired ceramic frit is durable and resists scratching, chipping, peeling, fading and chemical attacks. - Ceramic frit helps control heat gain, diffuse light, and can be toughened enough to gain 2 hr rating.

STRUCTURAL SYSTEMS

Example of a typical ceramic frit pattern

MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Materiality

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

View of Ceramic Frit in Whitman accentuating the directionality of the ‘Spine’.


12/5/11

TRANSLUCENT CERAMIC FRIT

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

ARCHITECTURAL DESIGN

- Ceramic enamel frits contain finely ground glass mixed with inorganic pigments to produce a desired color. The coated glass is then heated to about 1,150°F, fusing the frit to the glass surface, which produces a ceramic coating almost as hard and tough as the glass itself. A fired ceramic frit is durable and resists scratching, chipping, peeling, fading and chemical attacks. - Ceramic frit helps control heat gain, diffuse light, and can be toughened enough to gain 2 hr rating.

BUILDING AND SITE

ALUMINUM COMPOSIT PANNEL

STRUCTURAL SYSTEMS

View of Ceramic Frit in Whitman same as on spine to advocate the connectivity.

MECHAN ICAL SYSTEMS

- Aluminum Composite Panel is composed of non-toxic and low density polyethylene core between two sheets of aluminum by using “extrude and continuous composite” compositing production line. - The innovative product conception of seemingly contradictory properties such as excellent formability and stability, low weight and large sizes, brilliant colors and weather resistance,

PLUMBING SYSTEMS

- Though the core material does contain a small amount of combustible polyethylene, the main ingredient of the non-combustible mineral filled core does not permit the proliferation of flame and restricts smoke. It is a fire-safe material that passes mandatory requirements for exterior and interior application.It is an ideal material for external claddings, roof of pedestrian passage and other architectural applications.

ELECTRICAL SYSTEMS

Typical Aluminum Composite Panel post-production

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Materiality


12/5/11

ARCHITECTURAL DESIGN

SOPHISTICATED BUILDING MONITERING SYSTEM

PROJECT OVERVIEW

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

- Occupancy Sensor Controls: Monitor the occupancy of individual offices to ensure efficient lighting and HVAC systems usage.

BUILDING AND SITE STRUCTURAL SYSTEMS MECHAN ICAL SYSTEMS PLUMBING SYSTEMS ELECTRICAL SYSTEMS

Fins along fenestration functioning as occupancy sensor

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

FACADE + ROOFING

Occupancy Control


MARTIN J. WHITMAN SCHOOL OF MANAGEMENT Functional

Architectural Design

Building and Site

Structural Systems

Mechanical Systems

Environmental Systems

Programmatic Systems

Matrix

The function of the architecture is to create a seperation of program through the distinction of facade. The modernist brick facade encompasses the most private elemennts of program while the glass facades hold the more public or “usable” areas. The interior finishes of the design are chosen to mold the stark corporate buisness and public freedom ideologies together in a learning environment that is both successful and pleasant.

The buildings functional purpose is to become raised off of the site so that the water runoff of the building drains away from the structure and not towards it. It functions as a community building on the ground level and becomes privitized and focused on the program above the street level.

9/15/11 Contextual

Each of the material uses of the building engage the scale and character of the surrounding structures and allow for the city to move smoothly into the university atmosphere. These design elements remove the harsh contrast between the low lying building elements and the more graceful ideas of the campus buildings. The circulation within the design allows one to orient themselves within the site at all times while simultaneously unifying the volumes. The spine is raised above the rest of the building to help out-elevate the shadow that is cast by the Sheraton to the south. Contextually the building functions as a gateway to the university along one of the most important and occupied streets at the university. It responds to the recent expansion into the downtown area and is a landmark upon entering the real estate of the university. The surrounding buildings apart from the Sheraton Hotel are all low lying structures that do not create a lot of impact or attention. The ramp at the front of the building draws the community into the building at the first level.

The structural systems for the Whitman School of Management consists of a steel framing grid aligned with the intersection between programmatic differeces. The steel structure sits atop a concrete footing base aligned similarly. The structure of the building is exposed at many points within the structure allowing the skeleton of the building to show and giving the building a cool sense of value.

The structural systems are contextually used within the building through the use of steel framing and concrete footing. Many nearby structures including the marshall square mall as well as the Sheraton use this exact idea for their designs. In addition the majority of the surrounding structures are built into hillsides, or inclines, so the footings are ajusted accordingly to give correct support and stability.

The mechanical system works through a displacement ventilation. It supplies conditioned cool air crom the AHU through a low induction diffuser. This allowes the cool air to rise as it gets warmer creating a more comfortable environment for the occupants.

The cool air rises due to heat exchange with heat sources in the space so that the warmer air obtains a lower density thus creating an upward convective flows known as thermal plumes. this allows cool air to come in from outside on the lower areas of the spaces and escape through the higher spaces. The atrium is classified as an outdoor space so is cut off from the rest of the building and acquires its own systems.

The environmental systems work to incorporate the sun in terms of lighting, and the greenery from other areas in the vicinity of the site. The large atrium windows function to allow maximum light into the center of the building day and year round, as well as contribute to unobstructed views of the surrounding university. The greenery works to connect life within the building to the exterior

The environmental systems withing the building take from the context directly and incorporate the greenery within the building to make interior mesh with interior.

The programmatic function of the building is to establish a new urban fabric through the seperation of the building into seperate volumes that each take on its own function conected down the center by what could be called a small street on each level or “spine” that holds the volumes together. Each floor is color coded at the important entry points and accented wals to allow occupants to orient themselves and lower the required exit signs or directional notices or appliances. The classrooms are located in one area to express the jewl quality that is teaching/learning. Each classroom = interactiveness.

The contextual idea of the program is to give the building its own urban fabric through the seperation into individual volumes. It uses the form of the surrounding buildings brought together to maintain the volumetric context. The daylight thatpenetrates the building allows for a consistant linkto the exterior of the building.

Environmental

Pros and Cons

Intervention

The environmental design elements are numerous, one of which is the high-perfomance envelope that minimizes the energy use of the building. Others include below-floor air displacement, radiant cooling and heating in the atrium, highly efficient air filtration, occupancy radar system within the upper levels and distribution and a very high-tech building monitoring system. Every material chosen was picked for its low- VOC content as well as its ability to be recycled. These include carpets, paints, furniture and ceiling tiles.

Pro: The visual connection to the different programmatic concepts of the building through choice of material and design. High performance design and vigor in use of material. Speaks to the context of the site.

The building maintenance practices are developed at a high ability to ensure that the building does not loose its sustainable value over time. It was designed to progress and change to the needs of the university, whether those be social or academic allowing the buildign to hold more weight within integrity of the university.

Pro: The building allows for the site to be least impacted because it is raised as high as possible. The walkways accomodate ideas of connection to the university.

The structural system does not directly work to imporve the environment, as it is a steel frame basis with concrete footings.

Pro: The construction process reduces the cost of the building. Keeps the engineering simple. Common materials make it easier to acquire.

Usable upper exterior space. Louvres in atrium on exterior of building/ shading device.

Con: Exterior spaces on the roof are not used. The atrium can become hot because louvers are on inside so the heat has already entered the building.

Manipulate city side of building face

Con: The buildings “back” is turned to the gateway shutting the jem of the couryard out.

Alternate materials to increase sustainability?

Con: The sustainability rating of the design suffers for lack of reusable materials. Lack of aesthetic where structure is exposed. The systems of the building connect to the environment through the use of the atrium space primarily. It encompasses the exterior space within a living space within the building and is a buffer zone between inside and outside. The occupancy sensors on every window allow for a minimal excess use of lighting and air conditioning. They recognize when a room is occupied or vacant and turn on and off the systems of that room accordingly.

Pro: They work to increase the sustainability and environmentally friendly aspects of the design. They allow for more pleasant conditions within the occupied spaces.

Alternate cooling in atrium/ possible

Con: Does’nt keep atrium cool enough. Takes up space that could be communal.

The environmental systems are designed at a high integrity so that the building works in what seems to be the most efficient and sustainable way possible. Each system is designed to create low impact and maximize occupant comrfort while relating to the direct context and drawing from existing usage of ideologies.

Pro: They connect the environment and building that is otherwise always kept seperate. Allows for the feel of exterior space.

The atrium program allows the for the maximum sun exposure year round and for the most hours in a day.

Pro: Allows for the seperation of people and their studies. Allows for a communal space within the center of the program through the spine.

Con: Hard to maintain plants and their shed/ change.

Con: Seperates the communal space on the ground floor and the class space on the upper floors, and the professional space in the “seperate building”

Advanced Building Systems

Weston Halkyard

Integrate cafe/ social space to passing traffic.

Tanner Halkyard

Rhett Bruno

David Haberman


MARTIN J. WHITMAN SCHOOL OF MANAGEMENT Functional

Contextual

9/15/11 Environmental The environmental design elements are numerous, one of which is the high-perfomance envelope that minimizes the energy use of the building. Others include below-floor air displacement, radiant cooling and heating in the atrium, highly efficient air filtration, occupancy radar system within the upper levels and distribution and a very high-tech building monitoring system. Every material chosen was picked for its low- VOC content as well as its ability to be recycled. These include carpets, paints, furniture and ceiling tiles.

Architectural Design

Contextually the building functions as a gateway to the university along one of the most important and occupied streets at the university. It responds to the recent expansion into the downtown area and is a landmark upon entering the real estate of the university. The surrounding buildings apart from the Sheraton Hotel are all low lying structures that do not create a lot of impact or attention. The ramp at the front of the building draws the community into the building at the first level.

Building and Site

The building maintenance practices are developed at a high ability to ensure that the building does not loose its sustainable value over time. It was designed to progress and change to the needs of the university, whether those be social or academic allowing the buildign to hold more weight within integrity of the university. the green spaces within and without the building aid in the consistant high air quality.

Redesign DrawbackThere are some environmental design aspects of whitman that could be enhanced or changed. The first is the protruding occupancy sensorson the exterior of the brick-clad office segment. They hinder the windows in their ability to open and allow natural circulation to variate the microclimate within.

ChangeOur intervention for the occupancy sensor windows on the brick-clad office block, incorporates operable windows that allow natural air to enter the space and alter the otherwise completely air conditioned rooms. This change will optimally allow the HVAC (radiators and air diffusers) to work less to condition the air spaceas the occupancy sensors will sense that there is natural air circulation, therefore halting the need for constant conditioned air.

Drawback-

As a contextual gateway to the university, the design of whitman more or less turns its back to the city. The captivating design elements happen towards the entrance with the atrium, entrance walkway, and glass cladding. The brick facade relates to the context of the city but apart from the protruding element of the spine glass, does little else to announce the start of the University. A drawback to the environmental qualitiesof the building and site is that it minimally uses the idea of greenery within the design. The building claims that it draws from walnut park on campus in terms of trees and grass but it is of minimal use.

Change-

A proposed intervention for this drawback is a curved wall element that draws the public of downtown into the backside of the building in a more street like maner. The curved wall/ atrium is clad in yellow like the walls of the main atrium. it would open the backside of the building and visually draw the public into the program. A seperate idea of a green roof for the atrium contributes to the lack of green space in the urban fabric of the marshall street area. It would allow the roof which is otherwise a hot flat surface to be accessable.

Structural Systems

The systems of the building connect to the environment through the use of the atrium space primarily. It encompasses the exterior space within a living space within the building and is a buffer zone between inside and outside. The occupancy sensors on every window allow for a minimal excess use of lighting and air conditioning. They recognize when a room is occupied or vacant and turn on and off the systems of that room accordingly.

Mechanical Systems

Environmental Systems

The environmental systems work to incorporate the sun in terms of lighting, and the greenery from other areas in the vicinity of the site. The large atrium windows function to allow maximum light into the center of the building day and year round, as well as contribute to unobstructed views of the surrounding university. The greenery works to connect life within the building to the exterior

The mechanical systems within Whitman use an air displacement system which can control the air quality alreay found within the building. The drawback comes because of the lack of natural ventilation whithin the building as a whole. Everything is sealed off from the exterior which provides a clear seperation from the feeling of natural air flow.

Change-

The large intervention proposed, deals with the lack of air flow through the first three floors. the proposal pushes the offices back toward marshall street and uses the interior space to create an atrium that protrudes through the north wall to not only visually connect the building to the site movement and downtown, but funnels the windward breeze into the north side through the 5 floor atrium allowing for less wear and use of the air displacement system, and greater utilization of natural ventilation.

Drawback-

The environmental systems withing the building take from the context directly and incorporate the greenery within the building to make interior mesh with interior.

The design utilizes natural daylight in the atrium, upper hallways, and inside the classrooms, as well as through the normalized windows on the office mass. The design for natural daylight does not incorporate the ground floor level, or the shaded side of the north and north eastern side of the building. This creates greater work for the mechanical system through the greater use of artifical lighting.

Change-

The alteration can be considerd linked to the green roof proposal. The environmental systems for whitman can be enhanced through the use of the green roof’s rain/waste water collection abilities, the photosynthesis of the plants enhance the oxygen quality in the area, and connect to the park. The building will be able to save energy through the insulation and lessen heat gain during the summer. It would allow people to exerience these environmental system and would lessen wind load on the building. The atrium program allows the for the maximum sun exposure year round and for the most hours in a day.

Programmatic Systems

Drawback-

DrawbackThe drawback to having sunlight so exposed to such a large glass space is that the space becomes very hot very quickly when exposed with such little shading. The space has no outlets for the heat as the upper floors are completely cut off from the space, and therefore the heat can only escape through the small vents in the roof. The atrium uses things such as high albedo roofing to help cut down on heat but the problem still persists.

Change-

An alteration to this effect is to have the louvers in the atrium ajustable to allow for the complete block out of the sun at the hottest points during the summer months. This would decrease the heat affect within the atrium and decrease the need for air conditioning within the space. A second proposal is to have a thermal wall mass that would replace the otherwise programmaticly colored yellow wall. the mass would collect the direct heat of the penetratin sun and harnes it, releasing it into the space during the night which would be a more efficient system than air diffusers and strip vents, or an air displacement system.

Matrix

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman


Thermal Massing Wall

Thermal Massing Wall and Louvres + Adjustable Office Windows

Green Roof on Atrium

Natural Ventilation Break


12/5/11

Existing Space

- The total window area is about 50,000 ft, the thermal mass for this area is about 30,000 while the maximum area for 24,000 ft. The dominant heating method is an air displacement system, so the thermal mass can save about 12% heating load.

Day rendering showing new Concrete, Thermal Mass.

Natural Ventilation Break

Adjustable Louvers

Concrete, Thermal Mass

Existing Space

Thermal Mass

Night rendering showing new Concrete, Thermal Mass.

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Green Roof on Atrium

- A Thermal Wall in the atrium will allow us to store heat throughout the day during the cold months and radiate at night to provide warmth while the space is being used for studies at night.

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Rhett Bruno

David Haberman


Noon - December 21st Angle - 25*

12/5/11

Tracking Louvers using a mechanical Pulley System

10° 20° 30° 20:47

40° 50°

5:25

60° 70° 80° 19:19

6:42

- Making the Louvers track the low sun angle during the winter will allow more sunlightt to land upon the thermal mass. In summer they will remain at the same angle as how they curently exist, keeping most of the sunrays out of the space.

35* Noon - June 21st Angle - 66*

Thermal Mass

December 21st | 12 P.M.

25 degrees

Advanced Building Systems

December 21st | 3 P.M.

35 degrees

15 degrees

Weston Halkyard

Equinoxes 21st | 11 A.M.

Tanner Halkyard

Rhett Bruno

David Haberman

Natural Ventilation Break

5 degrees (Perpendicular to glass)

7:33

9 am Noon 3 pm 6 pm Sunrise/Sunset December 21 Equinoxes June 21

Green Roof on Atrium

16:33

Summer | Daily Winter | Sunrise and Sunset

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT


12/5/11

Adjustable Office Windows

Set-back Window slides across behind the Occupancy Sensor

Set-back Window slides back on track

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Green Roof on Atrium

Thermal Mass

Natural Ventilation Break

Existing

New

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman


12/5/11

Existing Office Windows

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Green Roof on Atrium

Natural Ventilation Break

Thermal Mass

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman


12/5/11

Operable Office Windows

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Green Roof on Atrium

Set-back Window slides back on track

Natural Ventilation Break

Thermal Mass

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman


Thermal Massing Wall

Green Roof on Atrium

Green Roof Atrium

Natural Ventilation Break


12/5/11

E F F I C I E N CY O F E N E R GY C O O L I N G 75% loss

Green Roof on Atrium

Tar roofing creates a heat gain that in turn, generates what is called heat island effect. This contributes to global warming as none of the energy is harnessed or used within the building. It forces the building s systems to work harder to actively heat and cool the interior.

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Conventional Tar Roofing

E F F I C I E N CY O F E N E R GY C O O L I N G 24% loss Increase in energy savings is temporary and labor costs are significant in comparison to saving. The 24 % loss in cooling energy savings after the first year is a result of dirt accumulation- minimizing the reflectiveness of the albedo.

Natural Ventilation Break

Used High Albedo Roofing

E F F I C I E N CY O F E N E R GY C O O L I N G 25% gain

Proposed Extensive Green Roofing Green Roof

The green roof curbes the urban heat island effect, allowing for the efficiency of energy use to become a gaining relationship. it uses the low lying plants to work as a blanket insulator to keep the heat out of the building in summer and inside during winter. A green roof helps in the city of syracuse because of the unpradictability of weather and it lowers the possibility of corrosion in areas like street and sewer areas through the efficient use of drainage and rain water to aid in the plant life.

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman


12/5/11

Average Roof Heat Flux

3.00

CONVENTIONAL VS. GREEN

2.00 1.50 1.00 0.50 0.00

Conventional roofs are what make up a large part of Syracuse city’s impervious survaces and contribute to two key problems. They create and urban heat island effect as well as urban storm-water runoff which contribute to the consumption of energy and increase the need for water as well as energy systems to deal with the excess of both that is produced. With the intervention of a green roof system , our goal is to cut down on our water and energy excess production and save both directly and indirectly. We plan to use the green roof to cover and provide a blanket of shade to reduce the heat gain of the surface area.

-0.50 1

3

5

7

9

11

HOUR OF DAY

13

15

17

19

21

19

21

Eastern Conventional Roofing- peak surface temp: 130 degrees at 1pm Eastern Green Roofing- peak surface temp: 93 degrees at 10pm

Average Roof Surface Temperature

The current system uses High-Albedo Roofing wich is a low heat gain material, however the affect the sun has on the atrium space calles for a 0 heat gain surface which the green roof can supply.

Natural Ventilation Break

140

o

Temperature F

120

100

80

60 1

Green Roof

Green Roof on Atrium

HEAT FLUX, BTU/h - ft

2

2.50

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Advanced Building Systems

3

5

7

Weston Halkyard

9

11

HOUR OF DAY

13

Tanner Halkyard

15

17

Rhett Bruno

David Haberman


12/5/11

EXISTING ATRIUM ROOF CONDITION

Green Roof on Atrium

“If I could change something about this buildinging, being a buisness finance student, it would be the fact that no one can go outside and experience the roof of the atrium which looks like it was meant to walk on. It is always locked but it would be awesome to see the view and hang out up there. I think they lock it because at some points during the year it gets so sindy, it could literally blow you over.” -Kelly class of 2012

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Natural Ventilation Break

Existing Roof Wind Condition Green Roof

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman


12/5/11

INTERVATION :ATRIUM ROOF CONDITION

Green Roof on Atrium

A green roof intervention will incorporate an extensive green roof design, meaning that it will contain shallow soil and low growing plants spread horizontally across the roof plane. They will consist of grasses and other succulents that can withstand and grow in the more extreme weather climates, including large exposure to sunlight and harsh winds.

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

The extensive green roof will be more cost effective than an intensive green roof, the other of its kind that uses more material to allow larger plants to grow, as well as a greater support system. The intervention will utilize the existing structure that is currently placed for aesthetic appeal and requires the minimal additional material .

Natural Ventilation Break

Proposed Roof Wind Condition Green Roof

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman


12/5/11

Plants/ Sedum -

MODULAR GREEN ROOF INSTALLATION - Inexpensive Installation

Lightweight, FLL-Approved Growth Medium Lighter weight that most topsoils, this growth medium works to drain storm water and is weed free. Its support capability is between 4.8 and 6 pounds psf per inch depth, and prevents harmful substances from flowing into runoff. It holds the water that is caught and does not compact once plan examples are granulated clay or shale mixed with organic compounds or fertilizer.

Oldroyd TP Filter Fleece-

minimize weight and optimize water management as well as prevents the water spread on the surface of the roof. Itprovides a simpler installation method, as there is an already existing grid on the roof.

Green Roof on Atrium

- Insulation allows the meeting of code while reducing excess roof insulation

The top layer consists of a variety of sedum (a low maintenance plant that can survive in the harsh conditions of Syracuse NY. It utilizes six different types of sexum: - Sedum refluxum, - Sedum sexangulare, - Sedum acre, - Sedum kamschaticum, - Sedum spurium “Fuldaglut” - Sedum album.

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Adhered Sure-Weld TPO Single-ply membrane-

heat weldable sheet that has a high breaking strengthand puncture resistance. resistance to UV rays, oxidation and is 100% recyclable

increases drainage rate and water holding capacity. Holds 1.63 pounds of water (0.2 gallons/ 0.31” of rain) crush resistance and strength.

Suitable Waterproof Membraneprovides moisture resistance to prevent water from entering below the sealant and into the space.

Adhered Moisture- Resistant Gypsum Board like the waterproof membrane the moisture-resistant board relieves underground water-created pressure and resists the penetration of water from under the green oof into the structure

Concrete Slab The bottom layer is a concrete deck slab with will provide the base for the green roof as well as span the distance for the new structural addition and strengthening areas.

Green Roof

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

Natural Ventilation Break

Oldroyd XV20 Green Xtra Drainage Layer (49-70% Recycled) -


12/5/11

PROPOSED GREEN ROOF CONDITION

PROPOSED GREEN ROOF CONDITION

Studies show that the plant life on the green roof minimize the amount of storm water runoff and the photosynthesis of the plantsreduces the amount of greenhouse gasses into the atmosphere.

Green Roof on Atrium

The flat feature of the high albedo roofing encourages dust and dirt to accumulate on the surface, therefore comprimising the integrity of the use of the material. It also forms a negative pocket of wind that neglects the use of the roof by the public.

Natural Ventilation Break

Accessibility

Tree Plant Boxes Growth Sedum Waterproof Layering

Intensified Structure

Green Roof

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman


12/5/11

SEALANT MEMBRANE Existing Structure Existing Concrete Slab

1 SQ FT OF GREEN ROOF

HIGH ALBEDO ROOFING

G R E EN R O O F I N G

Green Roof on Atrium

3 INCHES OF SEDUM 15-20 LBS PSF WHEN SATURATED 1-2 LBS OF PLANTLIFE .5 LBS OF FILTER MEMBRANE LIVE LOAD + OCCUPIED BY PEOPLE 2,979 SQ FT OF ROOF AREA ABOVE ATRIUM

- ALBEDO ROOFING + GREEN ROOFING = ADDITIONAL 62,559 + LBS OF GREEN ROOF

Green Roof

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

Natural Ventilation Break

1 SQ FT OF ALBEDO ROOF

H I G H A L B E D O R O O F I N G

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT


Thermal Massing Wall

Green Roof on Atrium

Natural Ventilation Break

Natural Ventilation Break


12/5/11

Green Roof on Atrium

Average Wind Speed- Syracuse 30 mph 25 mph 20 mph 15 mph 10 mph

Natural Ventilation Break

5 mph

JAN FEB

MAR APR MAY

JUN JUL AUG SEP OCT NOV DEC

Maximum Average

Adjustable Wind Tracking Fins that inhabit the ventilation break allow controlled natrual air to enter the windward side of the building lessening the requirement and use of the current HVAC system

Current Site Wind Flow Direction

Natural Ventilation Break

Average Wind Speed- Syracuse 30 mph 25 mph 20 mph 15 mph 10 mph 5 mph

JAN FEB

MAR APR MAY

JUN JUL AUG SEP OCT NOV DEC

Maximum Average

Intervention Site Wind Flow Direction

NATURAL VENTILATION BREAK

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman


12/5/11

Gathering Spaces Spaces along the ‘Spine’ which have become gathering spaces for students to work on the Concourse to Third level and for faculty events on the Forth Floor.

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Green Roof on Atrium

Existing 1st floor

NATURAL VENTILATION BREAK

Existing 2nd floor

Existing 3rd floor

Advanced Building Systems

Weston Halkyard

Natural Ventilation Break

Existing Comcourse

Existing 4th floor

Tanner Halkyard

Rhett Bruno

David Haberman


12/5/11

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Green Roof on Atrium

Natural Ventilation Break

Strip vents

Plan showing existing condition

Section showing existing condition

NATURAL VENTILATION BREAK

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman


12/5/11

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Green Roof on Atrium

NATURAL VENTILATION BREAK

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman

Natural Ventilation Break

Section showing intervention and movement of program to the East tower


12/5/11

Occupants within the building prefer natural ventilation and air, therefore the opening of the windward North side of the building would draw the wind through the corridor (streets) making this idea of natural ventilation feasable. The pressure differentiation from the north to the south building with the wind movement draws air through the hallways and up through the atrium allowing the occupants to experience a change from the artificially conditioned air in the current design.

Green Roof on Atrium

Passive Ventilation Systems Concourse Level

Natural Ventilation Break

First Floor

Second- Fourth Floor

NATURAL VENTILATION BREAK

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Rhett Bruno

David Haberman


12/5/11

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Green Roof on Atrium

NATURAL VENTILATION BREAK

Natural Ventilation Break

Warm Exterior Temperatures- Showing the Louvers in their open stage to allow for natural ventilation from the windward side

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman


12/5/11

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Green Roof on Atrium

NATURAL VENTILATION BREAK

Natural Ventilation Break

Cold Exterior Temperatures- Showing the Louvers in their closed stage to allow for the building to gain heat in the winte

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman


12/5/11

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Green Roof on Atrium

Natural Ventilation Break

NATURAL VENTILATION BREAK

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman


12/5/11

The original Structure does not allow for natural ventalation to pierce the spine through the windward side of the building.

Origional Structure Conditioined air is brought up through the air ventilation system and artificially conditions the spine.

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Green Roof on Atrium

Natural Ventilation Break

NATURAL VENTILATION BREAK

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman


12/5/11

Peeling the windward facade open calls for a manipulation of the structure attached to the spine therefore scaling down the office and cafe program on the maine street side of the building. To make up for the loss the extracted program will be placed on the top of the 6th floor non street side of the office zone

Manipulated Structure

Green Roof on Atrium

with intervention fresh air can be supplied to the communal spaces overlooking the atrium on the second and third floors as well as the spine of the building and tha atrium during the warm months of the year

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Natural Ventilation Break

NATURAL VENTILATION BREAK

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman


Design Capacity (kBtu/h)

Design Flow Rate (ft3/min)

185617

1470.4

Sensible (kBtu/h)

1103.3

Latent (kBtu/h)

327

Humidity (%)

464.7

Floor Area (ft2)

Volume (ft3)

f3/min (ft2)

29315.1

469110

44.62

Green Roof on Atrium

1644.3

Total Cooling Load (kBtu/h)

12/5/11

I N T E R V E N T I O N C O O L I N G L O A D J U L Y 1st

159

12,527

97.4

258.8

29.3

1803.3

NATURAL VENTILATION BREAK

Design Flow Rate (ft3/min)

198144

Total Cooling Load (kBtu/h)

1568

Sensible (kBtu/h)

Latent (kBtu/h)

1211.6

356.3

Humidity (%)

464.9

Advanced Building Systems

Floor Area (ft2)

29315.1

Volume (ft3)

f3/min (ft2)

469110.1

44.96

Weston Halkyard

Tanner Halkyard

Natural Ventilation Break

E X I S T I N G C O O L I N G L O A D J U L Y 1st

Design Capacity (kBtu/h)

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Rhett Bruno

David Haberman


12/5/11

0 -2000 -4000

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

-6000

Green Roof on Atrium

-8000 -10000 -12000 -14000

MODIFIED COOLING LOAD APRIL-JUNE

0 -2000

Natural Ventilation Break

-4000 -6000 -8000 -10000 -12000 -14000

ORIGIONAL COOLING LOAD APRIL-JUNE

NATURAL VENTILATION BREAK

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman


12/5/11

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Green Roof on Atrium

Natural Ventilation Break

Intervention effect on current lighting

NATURAL VENTILATION BREAK

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman


12/5/11

Thermal Massing Wall

MARTIN J. WHITMAN SCHOOL OF MANAGEMENT

Green Roof on Atrium

Natural Ventilation Break

NATURAL VENTILATION BREAK

Advanced Building Systems

Weston Halkyard

Tanner Halkyard

Rhett Bruno

David Haberman


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