The new Helsinki central library serves as an extension
of the natural park surrounding it. The park filters itself into the library traveling
from the West to the East of the city block becoming “trapped” into building
structure. The park pushes the masses both horizontally, North and East, and
vertical, ground to ski. The result is a U shape building elevated thought a
ramp traveling from the ground level and culminating in a roof terrace.
Furthermore, the horizontal force of the park divides the building into two
wings, North and East and transforms itself into an interior reading garden. Horizontally,
the building is connected by the café at the ground level and the restaurant
and sauna at the top level liked by a direct elevator. The trapped park forms two panoramic windows seeking
to scape looking in the direction of the parliament building to the West and
Alexandria to the South. All the knowledge brought into the library by the city
through the park makes the new Helsinki central library the brain of the
metropolis; a direct receiver and transmitter of information and excitement
clearly reflected by its constant ever-changing program of events and its
permanent collection of knowledge.
DURA MATER
The BRAIN of the Metropolis
HELSINKI CENTRAL LIBRARY
“Dura Mater is a thick and dense, inelastic,
fibrous membrane which lines the interior of the skull. Its outer surface is
rough and fibrillated and adheres closely to the inner surface of the bones,
forming their internal periosteum, this adhesion being most marked opposite the
sutures and at the base of the skull. Its inner surface is smooth and lined by
a layer of endothelium. it send four processes inwards, into the cavity of the
skull, for the support and protection of the different parts of the brain.”
[Gray’s Anatomy, Henry Gray and H.V.
Carter]
The concept for the New Central Library of
Helsinki is based on the Human Brain,
metaphorically connecting the city of
Helsinki with its natural creative engine, the Library,. Alike the Human Brain,
whose various areas meet different functions, the library is organized in very
different zones and functions, some completely opposite in characther and
nature.
These funtions are all “kept together” by the exterior
building envelope which creates a sort of continuity and consistency throughout
the building. Similar to the Dura Mater of the brain, the Library envelope
carries information both to its users and as a response to the environment
around it.
Spirit, Mind, Body
The Library is accessible on its roof via a
ramp that begins at grade on the main piazza. The promenade ascension is both a
physical experience of the changing city scape and the spiritual counterpart to
the idea of “change” in mind. Similar to Dante’s journey, the sloping uphill
can be experienced as a transformative moment, arriving at the top floor room
which faces south towards Alexandria and
the Finnish Parliament.
IMPACT OUT
Alexandria and the Parliament
The Library ultimate view points are the two large
window-rooms of the top floor restaurant, Jazz bar and Sauna. These spaces face
west and south, aligning respectively with the Parliament and House of Music,
and the trajectory of the Alexandria Library in Egypt. These views activate a
connection to the past, present and future of the library and welcome visitors
to re-experience it in a forward thinking dimension.
IMPACT IN
Full space and Lobby Garden
Inside the Library spaces are diverse, complex and
exciting. Organized around the central garden lobby, which can be designed as
an enclosable winter garden, the two main wings of the library and the east and
west bridges act as extension branches from the central garden core, similarly
to the beautiful and serene areas created around the trees.
URBAN LOCI
Reciprocal Feeding
The Library acts as a receiver and emitter of information
creating a “8” figure loop with the city of Helsinki and the World at large.
Different from an enclosed enclave which protects knowledge, the Dura Mater
Central Library collects and spreads knowledge at the broadest possible scale.
MAIN
STRUCTURAL SOLUTIONS AND HVAC TECHNICAL SOLUTIONS
(Operational principle and factors affecting the energy
performance)
OVERALL TECHNICAL STRATEGY: DURA MATER PERFORMANCE ENVELOPE
This building is designed to use the building envelope as
the primary thermal and electrical generator and regulator and uses the
district heating, cooling and grid electricity as efficient back-up. The
technical systems of this building are primarily housed within the
multi-layered assembly of the building envelope carrying an interior and
exterior narrow planar cavity or plenum for the flow of energy and material
(hydronic heat, ventilative air, DC electrical). A translucent insulative core
of aerogel, luminous concrete or motorized shading is bounded on both interior
and exterior by these cavities and the surface is enclosed with and interior
and exterior dual pane insulated glazing units.
This sophisticated jacket allows overall capillary-scale distribution of
heat, air and electricity to all areasof the building and assists the building
to distribute, balance and exchange the heat produced and heat consumed; fresh
air delivered and stale air exhausted, electrical energy generated and
electrical energy consumed in a constant flow of self-regulation, assisted by a
full network of skin-integrated sensors.
The intelligent envelope plugs into the four vertical
shafts at the north end, south end and center of the building plan to gather
distribution vertically and connect to the building center mechanical area in
order to plug into a central brain unit, heat exchange, electrical control,
water to water heat pump, air supply and exhaust, as well as the connection to
the district heating and cooling.
ENERGY SUPPLY SOLUTION
The building will utilize district heating and cooling
along with grid electricity only when the collection, exchange and balancing
capacity of the intelligent envelope requires additional energetic input. Water-to-water heat pumps will be employed to
provide cooling and/or heating required for the building as the inputs required
to balance the whole of the integrated system flows.
The building envelope incorporates building integrated
photovoltaic panels (BIVP) in the exterior insulated glazing unit on surfaces
facing SE, S and SW to produce electrical power.
The building envelope operates as a neural network of
production collection and distribution for heat, air and electricity, coordinated
by a large network of sensors throughout the same surfaces. These are connected together through a central
responsive logic and uses the district heating and cooling connection and grid
electricity as back-up when required or more efficient than the building scale.
HEATING
Heat is gathered through the hydronic medium such as
glycol in the exterior capillary cavities from solar radiation and collected from
the continuous full-envelope flows of the hydronic system and air system with a
central heat exchanger. The building heat pump efficiently boosts the skin
collection with much higher efficiencies and the intelligent HVAC controls use
the district heating when more efficient than the building scale collection. The
insulated translucent envelope assembly will carry the hydronic heat medium such
as glycol on the interior cavity or narrow plenum, providing radiant surfaces throughout
the building to heat the occupants and spaces.
STRUCTURES
The U value of the continuous envelope is kept as a super
insulated assembly of U=0.102 W/m2K.
This is typical for the dual pane IGU, hydronic or air plenum, aerogel
core, plenum plus dual pane IGU. For the glazed areas that provide view, a
quad-pane IGU becomes the core of the two plenum spaces and the interior and
exterior additional dual IGUs.
Exterior capillary plenums between the translucent insulated
core of the envelope assembly and the exterior IGU provide areas for collecting
solar thermal heating of water on clear days and BIPV in the exterior IGU
generate electrical energy when solar energy is available. Interior thermal
mass in the floors and structural members will buffer the potential temperature
swings and help to naturally regulate the temperature in the building.
WINDOWS
The entire envelope acts, in various degrees, as a light
transmitter, but there are areas that become “windows” with clear glass for
views in and out, especially to the plaza to the west, the large north view,
the framed south views and the views to the courtyard. These are composed of the typical multi-layer
skin described above, with the core aerogel removed and the expanded plenum
dedicated to shading provision. The spectrally selective exterior insulated
unit allows through only about one quarter of the potential heat gain with a g
value of 0.27 and the low-e coating reduces radiant transfer from inside the
building to the exterior. Conductive
heat loss is limited by the dual-dual IGU assembly with a U value = 0.372
W/m2K.
The glass is butt-glazed and adhered to a unitized
structural phenolic frame system that is low-conductance, a low
thermal-expansion coefficient and isolates the exterior glass thermally.
Solar shading is integral in the core area of the
envelope plenum and is tuned to the orientation with horizontal and vertical
louvers motorized and operated with the responsiveness of the neural network of
sensors and central programmed controls to shield the direct sun when either
visually uncomfortable or a thermal liability.
LIGHTING
Lighting for the main spaces is provided by both the
translucent skin and window/skylight areas so that lighting is first and primarily
through available daylight and moves seamlessly through controls to an
efficient electrically lit building during the dark hours. Smaller spaces share
the same strategy with fewer clear window areas to minimize heat loss. Daylight and occupancy sensors in the
building envelope will deliver information to the controls to maximize the use
of daylight and to keep the interior from becoming darker than desired. The lighting system will integrated into the
inside surface of the skin and interior partition walls and ceilings as LED
diffusing panels powered by the DC distribution system of the envelope. This daylight and diffuse electrical light
will be complimented with strategically placed arrays of small highly efficient
LED sources to add sparkle and localized area lighting. These are also managed by an intelligent
control system, a smart node that will respond to the system of deployed
sensors. This is designed to ensure that
the electric lighting is glare free and will supply only the light needed.
Installed lighting power will be an average of 5 watts
per square meter, while the effective lighting power density due to day light
and occupancy response will be 1.8 watts per meter square.
VENTILATION
Ventilation air is introduced to the building through the
four vertical shafts and gathered into the central mechanical space to be
thermally moderated by the exhaust air through heat exchange. The fresh air is distributed via the interior
plenum of the building envelope which contains small valves to release the
pressurized air to the interior spaces, much like an under floor air plenum
that is instead incorporated into the envelope itself.
Ventilation will be provided to provide the stated air
change rates. This air will be minimally conditioned to be delivered at close
to room temperature. Additional heating, cooling and dehumidification will be
provided via heat pumps or district heating/cooling systems based on the
seasonal carbon/energy profile of these resources. A high-efficiency heat recovery wheel will be
provided to capture free heating or cooling from the building relief or exhaust
stair stream. Additional free heating will be provided by capturing” greenhouse
effect” heat from the double-wall system.
Demand controlled ventilation will be provided via CO2
and VOC sensors strategically located within the building envelope. The SFP values include 2.5 for the central
mechanical ventilation including heating, cooling, heat recovery, 2.0 for the
central mechanical ventilation including heating and cooling, and 0.5 for the
envelope-local ventilation within the spaces.
COOLING
Cooling is a small load for the climate and since the
building envelope is designed to be a continuously responsive envelope
balancing out heat sinks and heat sources, additional cooling requirements will
be much lower than additional heating requirements. Nevertheless, cooling may
be needed for occupant comfort. The
courtyard places a primary role is providing access to natural ventilation through
the courtyard skin, which is operable for air movement, unlike the exterior
building skin. Intake through the courtyard skin and exhaust through the
vertical stacks of the building allows natural air flow during months when the
outside temperatures are comfortable. If the capacity of the thermal mass and
natural ventilation to cool the building is exceeded, district cooling and/or
the building heat pump will provide cooler fluid to circulate through the
envelope interior plenum, providing radiant cooling for comfort.
District or heat pump cooling will be provided for
network rooms and other spaces with high heat loads and/or controlled 24 hour
cooling needs.
DOMESTIC HOT WATER
The integrated envelope carries fluid that can be exposed
to the solar radiation and collected for domestic hot water. This will need to be supplemented during the
winter months with heat pump or district hot water that can be utilized for
domestic hot water generation via heat exchanger for large restroom fixture
groups. Single isolated restrooms will utilize instantaneous electric water
heating.
