ZEMCH 2015 - International Conference Proceedings | Page 331

Table 6: Common Set of Intelligent Building Technologies found in all Case Studies
Set 1

Set 2 (Set 2 comprises of Set 1 + the IBTs below)

Lighting Management System

Intelligent Security system- integration of CCTV, entry control
devices, alarms and emergency security lighting

Occupancy, Daylight sensors and Programmed timers for
lighting

Surveillance system with real time security feeds

Operable windows and sun-shades with night-time air flush

Computerised Smartcard access control system with proximity
and contact cards

Intelligent HVAC system with zoning and heat recovery

Intelligent Visitor Access System

Demand controlled ventilation system with CO2 monitoring

Fire Protection System incorporating fire detection and
Automatic sprinkler system

Space temperature sensors

Fire Protection system integrated with HVAC system to
automatically cut off zones where smoke is detected

Occupancy sensors for plug loads

Addressable fire safety detectors to continuously take air
samples and detect unusual fog

Sub-metering

CCTVs all over the building for fire monitoring

PIR taps

Smoke exhaust system that activates during a fire

Water leak detection system

IAQ management plan with temperature & humidity sensors
and UV emitters

Water usage monitoring

Refrigerant leak detection system

Energy usage monitoring

Automated Destination-controlled lift system

CO2 emissions monitoring

Elevators with Smart Card access system

IT networks for data transfer, integration and
telecommunication (ICS)

Guard Tour System to track security inspections

Simulation tools for energy, light and economic modelling

Multiple communications risers

Building Management System (BMS)

Intelligent AV control systems

Energy Management System (EMS)

Intelligent Document management system

Facilities Management System (FMS)

Soil moisture sensors
Solar tracking devices for PV panels
Simulation tools for airflow and temperature modelling

It can be observed that almost all of the IBTs in Set1 contribute towards resource efficiency. These
IBTs help with energy and water savings as well as CO2 reductions, hence leading to a linear rise in
the graph. This led them to follow a linear path such that as intelligence increased, sustainability
also increased. On the other hand, the buildings with a high number of IBTs usually had a larger
variety of technologies in terms of their core intelligence function- resource efficiency, interaction, safety, comfort, etc. The IBTs in Set2 also contributed towards resource efficiency but at the
same time there were a number of other IBTs used that primarily aided with other things such as
convenience, comfort, security, increased connectivity, etc. This caused their sustainability scores
to increase but not in a drastic one-to-one linear fashion but in a gradually rising curve. It can be
inferred that the score increased due to the resource efficient IBTs present, but the score was adversely affected by some of the other IBTs. Though many of the technologies in Set2 are of higher
intelligence, and continue to improve the overall intelligence of the building, they may not necessarily contribute towards the sustainability of the building in terms of the prescriptive parameters
set by LEED and BREEAM rating systems.
For example, lighting systems with occupancy and daylight sensors were created to improve energy efficiency. They were specifically designed to make energy saving smarter, while there are
other systems:
• Intelligent Security and access control system whose role is to make buildings safe.

Building intelligence and sustainability using leed and breeam in the UK and Europe

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