CHILLED BEAM

CHILLED BEAM
GUIDED BY:
Ms. Meera G Mohan
Assistant Professor(Civil)
SBCE
PRESENTED BY:
Neelima Suresh J
Roll No : 39
1

OVERVIEW
 Introduction
 Literature review
 Components of chilled beam
 Types of chilled beam
 Advantages of chilled beam
 Disadvantages of chilled beam
 Case study 1
 Case study 2
 Conclusion
2

INTRODUCTION
 A chilled beam is a type of convection HVAC system
designed to heat or cool large buildings
 Developed in Norway in 1975
 Emerging technology in the U.S. as an alternative to
conventional systems such as VAV
 Primarily used in locations where the humidity can be
controlled
3

LITERATURE REVIEW
SL
NO.
TITLE AUTHOR, YEAR CONTRIBUTION
1 Chilled Beams Selection
Dan int-hout and
W.Lilli , 2014
Describes the process
for selecting chilled
beams.
2
Applying chilled beams to
reduce building total carbon
footprint
Tim Dwyer, 2014
Applications of chilled
beams for energy and
carbon reduction
3
Chilled Beams Performance
Research
John Tomkin,2013
Analysed the
performance of hvac
system.
4
Chilled beam study claims
potential for 20 per cent
energy savings over fan coils
Andrew Gaved,2013
Shows a major energy
benefit for the
technology against
other systems
4

COMPONENTS OF CHILLED BEAM
1) Air handling units
 Major component within any chilled beam or chilled ceiling
system
 Role - to clean and condition the air as it enters the building
 Distribute it through the terminal devices
5

2) Mixing boxes
 Dampers are used in mixing boxes to regulate the mixture
of fresh air and re-circulated air
3) Coils
 Heat exchangers designed to transfer the energy from a
medium (usually water) to the air
 Individual coils for heating and cooling
6
COMPONENTS OF CHILLED BEAM
(contd..)

TYPES OF CHILLED BEAMS
 Active chilled beams
 Passive chilled beams
 Multi purpose chilled beams
7

ACTIVE CHILLED BEAMS
 Have ductwork supplied to them
 Through duct work specific amount of primary air is
provided to the pressurized plenum within the device
 The air is discharged through induction nozzles
 Mix with entrained air, and ventilate the room
8

9
Fig.1 Active chilled beam
(Source: John Murphy -understanding Chilled Beam Systems,2012)

OPERATION OF ACTIVE CHILLED
BEAM
 Fresh air from the air handler via duct work is supplied
into the pressure chamber
 Pressure in the chamber causes the air to rush out
through the nozzles at a high velocity into the mixing
chamber
 Due to nature of the nozzles, a low pressure system is
created above the coil
10

 Inducing more air through the coil into the mixing
chamber
 Conditioned air from the space mixes with the fresh air
 Supplied back into the room through linear slots located
along the casing of the beam
 The air gets supplied back to the space through the
linear slots at a higher velocity and at its coldest state
11
OPERATION OF ACTIVE CHILLED
BEAM (contd…)

12
Fig .2. Gordon House renovated using chilled beam
(Source: claremoorearchitect.blogspot)

PASSIVE CHILLED BEAMS
 Chilled beams work using natural convection
 Good air circulation is essential for the operation of
passive chilled beams
 Good solution to provide sensible cooling in labs or
other spaces where processes generate high heat
13

14
Fig.3 Passive chilled beam
(Source: John Murphy -understanding Chilled Beam Systems,2012)

OPERATION OF PASSIVE CHILLED
BEAM
 Arranged at regular intervals along the ceiling plane
to provide uniform cooling to the occupied space
below
 Consists of a fin-and-tube heat exchanger, contained
in a housing , that is suspended from the ceiling
 Chilled water passes through the tubes
15

 Warm air from the space rises toward the ceiling
 The air surrounding the chilled beam is cooled
 It descend back toward the floor
 This allows a passive chilled beam to provide space
cooling without the use of a fan
16
OPERATION OF PASSIVE CHILLED
BEAM (contd…)

Fig .4 Peabody Hall renovated with passive chilled beam
(Source: Chilled beams maintain comfort, look of historic hall-
SEMCO)
17

MULTI-SERVICE CHILLED BEAMS
 Comes in both passive and active types
 Incorporate other building systems into the beam in a
prefabricated unit
 This prefabricated unit can be brought to the project site
 Reduces the amount of time required to install all the
building systems
18

MULTI-SERVICE CHILLED BEAMS
(Contd…)
 Light fixtures and controls, speakers, occupancy sensors,
smoke detectors, and even fire sprinklers can be incorporated
into the beam
 The site delivery can be regulated to site requirements
 Reduces the total amount of space required for onsite storage
 Enables rapid installation and services connections with a
major saving in onsite time
19

20
Fig.5 Multiservice chilled beam
(Source: An Introduction to Chilled Beams and Ceilings,2012)

21
Fig.6. Multiservice chilled beam
(Source: An Introduction to Chilled Beams and Ceilings,2012)

ADVANTAGES OF CHILLED BEAM
 Quieter than air based HVAC systems due to the lack of
moving parts and slower air velocities
 Maintenance is also reduced due to the lack of moving
parts
 High indoor air quality resulting from air recirculated
within the zone versus mixed air from other zones
 Lower energy consumption
22

 Space savings resulting from reduced ductwork size
 This air conditioning unit provides excellent thermal
comfort with good energy efficiency
 Lower operation costs throughout the lifecycle of the
building
23
ADVANTAGES OF CHILLED BEAM
(Contd…)

DISADVANTAGES OF CHILLED BEAM
 Initial cost of chilled beams is typically higher than
when compared to other all air systems
 Chilled beams require more ceiling area than diffusers
of a conventional system
24

CASE STUDY 1
RENOVATION OF AN INDUCTION SYSTEM
WITH ACTIVE CHILLED BEAMS
25

CASE STUDY 1(contd…)
 250 S. Wacker in Chicago is a multi-tenant 15 story
office tower
 The first and top floors had dedicated HVAC systems
separate from the system serving the 2nd through 14th
floors
 These intermediate floors had a floor-mounted induction
perimeter system and a constant volume-variable
temperature interior system
26

 The existing induction units and enclosures would have
to be replaced as they were at the end of their useful life
27
Fig.7. 250 S. Wacker chicago
(Source: Renovation of an induction system with active chilled beams,
air/pro associates)

28
COMPARISON
Perimeter System Existing Induction Active Chilled Beam
Design Cooling Load
262 tons
(382 sq. ft./ton)
156 tons
(641 sq. ft./ton)
Primary Airflow
from Central AHUs
47,135 CFM
(0.47 CFM/sq. ft.)
31,760 CFM
(0.32 CFM/sq. ft.)
Fan Energy at
100% of Design
64 kW 22 kW
Pump Energy 28 kW 12 kW
Table 1. Comparison before and after renovation

CASE STUDY 2
UC DAVIS SEGUNDO STUDENT SERVICES
CENTER
29

 It is a new 34,500 square foot community center/
administrative center
 Located within the Segundo Precinct of the University of
California – Davis campus
30

ENERGY EFFICIENCY
 The project was able to achieve 42.3% energy savings
 Heat recovery and direct evaporative cooling systems
on the main air handling unit
 Chilled beam-VAV system: AHU was used to provide
primary air to the chilled beams for the perimeter
spaces
31

ENERGY EFFICIENCY (contd…)
 Demand control ventilation strategy which was possible
by having a VAV box upstream of the chilled beams
 High performance glazing systems with integrated
shading systems
 Thermally broken insulating wall system
32

 INDOOR AIR QUALITY
 The chilled beam system operates close to the outdoor air
requirements for occupancy
 This allowed the design to be based on 100% outside air
 The internal spaces had their cooling airflows close to the
outdoor air requirement which allowed them to be fed from
the same unit
33

 COST EFFECTIVENESS
 The energy efficiency measures and innovative systems
selected proved to be very cost effective
 ENVIRONMENTAL IMPACT
 The Segundo Service Center was able to reduce invasive
piping and energy consumption
34

 ENVIRONMENTAL IMPACT (contd..)
 The building was able to achieve an annual CO2
reduction of 241.8 metric tons
35

36
Fig.8. Uc davis segundo student services centre
(Source: Case study on uc davis segundo student services center, guttmann
and blaevoet)

CONCLUSION
 Chilled beams remove large amounts of sensible heat
 Active chilled beam reduces primary air flow requirement
 The lifecycle cost of chilled beam system is lower than in
other cooling systems
 The energy consumption of beam system is low
 The chilled beam system reduces carbon dioxide emission
to a greater extent
37

REFERENCES
 Chilled Beam System Market by Design (Active, Passive, &
Multi-Service) worth $406.8 Million by 2020, digital journal,
June 2015.
 Dan int-hout and W.Lilli , Chilled Beams Selection, ASHRAE
Journal, November 2014, Vol. 56 Issue 11, page58.
 Chilled Beams Performance Research- Ceiling the Deal, CIBSE
Journal, November 2013, page 21.
 CBCA article on An Introduction to Chilled Beams and
Ceilings, RAC Journal February2013, page 16.
 Chilled beam study claims potential for 20% energy savings
over fan coils - RAC Journal, Augest2013
38

CHILLED BEAM

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