Building Service Project 2 Year 2016 (Taylors University Lakeside Campus)
1. BUILDING SERVICE SYSTEMS FOR
ELDERY CENTER @
TAMAN KANAGAPURAM
BUILDING SERVICE
BLD 60903/ ARC2423
PREPARED BY :
ROY YIEK CHEN HIENG 0317726
ONG SENG PENG 0319016
SONG SUNG HO 0322100
JACK SIA HONG JIE 0323506
SHAM ZHEN WEN 0317733
LEE CZEN SHING 0317832
TUTOR/ LECTURER:
DR. SIVARAMAN KUPPUSAMY
2. Table of Content
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Abstract ………………………………………………………………………………….. 2
Acknowledgement………………………………………………..................................... 3
Introduction to The Building ……………………………................................................. 4
Findings and Analysis
1.0 Fire Protection System
1.1 Introduction to Fire Protection…………………………………………………….5
1.2 Literature Review for Fire Protection …………………………….........................6
1.3 Components of Passive Fire Protection …………………………………………..7-12
1.3.1 Fire Door and Exit Sign ……………………………………………………….
1.3.2 Means of Escape ………………………………………………………………
1.3.3 Fire Escape Stairs ………………………………………………………………...
1.4 Components of Active Fire Protection ……………………………………………13-17
1.4.1 Fire Hydrant …………………………………………………………………..
1.4.2 Dry Riser and Hose Reel System ……………………………………………..
1.4.3 Fire Extinguisher ……………………………………………………………...
1.4.4 Two Stage Fire Alarm System………………………………………………....
1.4.5 Proposed Fire Protection Layout Plan For Elderly Center …………………....
2.0 Air Conditioning System
2.1 Introduction to Air Condition System …………………………………………….18-25
2.0.1 UBBL Part III – Space, Light and Ventilation………………………………...
2.2 Literature Review for Air Conditioning System ………………………………….
2.3 Basic Components of Air Conditioning System…………………………………….
2.4 Operation of air conditioning system ……………………………………………….
2.4.1 Type of air-conditioning system for small building …………………………..
2.5 Proposed Air-Conditioning System Layout Plan ………………………………….
2.6 Proposal for of air conditioning system
3.0 Mechanical Ventilation System
3.1 Introduction to Mechanical Ventilation System …………………………………..26-35
3.2 Literature Review for Mechanical Ventilation System …………………………...
3.3 Component of overall Ventilation System ……………………………………….
3.4 Supply Ventilation System ………………………………………………………..
3.5 Extract Ventilation system ………………………………………………………..
3.6 Proposed Mechanical Ventilation Layout Plan For elderly Center ……………….
4.0 Mechanical Transportation System
4.1 Introduction to Mechanical Transportation ……………………………………….36-42
4.2 Literature Review for Mechanical Transport System …………………………......
4.3 MRL(Machine Room Less )- Hydraulic Elevator System ………………………..
4.3.1 Component of System …………………………………………………………
4.3.2 Operation of System ………………………………………………………......
4.4 Proposed Hydraulic Lift Plan &Section Dwg for Elderly Center ………………...
5.0 Conclusion ……………………………………………………………………………43
6.0 References ……………………………………………………………………………44-45
3. Abstract
In this report, we are required to choose one of the group member’s design scheme for
Semester 4 Design Studio Project, Elderly Center, and perform a throughout study of the
UBBL By-laws and analysis of the services systems associated to the chosen building and
propose a suitable system for the building. The services that we will look into are :-
i. Mechanical Ventilation
ii. Air-Conditioning System
iii. Passive and Active Fire Protection System
iv. Mechanical Transportation
After the gathering of information from analysis and researches, a conclusion will be
conducted to these services based on our understanding.
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4. Acknowledgement
We would like to express our deepest gratitude to each individual that has contributed in any
way upon the completion of this report within the given time. This report is the effort and co-
operation from our group members, Roy Yiek, Jeff Ong, Sung Ho, Hong Jie, Sham Zhen Wen,
and Samantha.
We would also like to express our deepest appreciation to our tutor, Dr Siva for providing us
with guidance to complete this report and giving us very useful suggestions during our tutorial
sessions. By all means, we would like to thank once again to everyone who had contributed in
making this report a success.
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5. Introduction to building
ELDERY CENTER @ TAMAN KANAGAPURAM, JALAN 18/16
This proposed elderly center is a public building located at Jalan 18/16, Taman
Kanagapuram, Old Klang Road. The built-up area for this center is 800 sq meter.
The aim of this elderly center is to provide a place that function as a gathering spot for the
elder community at Taman Kanagapuram to gather around, having activities and socialize
with each other. This center will provide spaces such as office, studio room, kitchen,
cafeteria, gallery plaza, game room and etc.
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1.1 Introduction to fire protection
Fire is a chemical reaction comprises of 3 factors:
oxygen, fuel and heat, without any of these, fire won’t
be produced.
Therefore fire protection in a building should be
focusing on limiting the interaction of fuels and
ignition sources.
1.0 Fire Protection System
Fire protection consideration must be involved in every part of the building in order to
ensure the safety of the inhabitants from fire and smoke in case of accident.
A fire protection system can be divided into two types, namely the active fire protection
(AFP) and the passive fire protection system (PFP). AFP uses systems that take action in
putting out the fire, while PFP uses systems that help prevent the spread of fire and
smoke.
Common fuels that ignites the fire in building could be paper, wood and plastic furnishings,
clothes, gases, and other combustible components present in the building. Typical ignition
sources could come from electrical and lighting equipment, heating and air-conditioning
systems, cigarette use, cooking, office equipment, extension cords, food and beverage
preparation, and warming equipment.
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1.2 Literature Review for Fire Protection
Passive fire protection system is an integral component of the structural and fire safety in
a building. Passive fire protection systems allow fire to act upon the system itself, to
compartmentalize and contain the fire to save lives and protect the structure such as load
bearing column and beam from collapsing prematurely in event of fire. Passive fire
protection does not rely on the operation of any mechanical device in order to be
activated.
Active Fire Protection (AFP) is a group of systems that require some amount of action or
motion in order to work efficiently in the event of a fire. Actions may be manually operated,
like a fire extinguisher or automatic, like a sprinkler, but either way they require some amount
of action. AFP includes fire/smoke alarm systems, sprinkler systems, and fire extinguishers as
well as firefighters. Fire/smoke alarm systems are used to detect whether there is fire and/or
smoke in a building. Sprinkler systems are used to help slow the growth of the fire. Fire
extinguishers and firefighters are used to help put out the fire altogether.
8. 230. (1) Dry rising systems shall be provided in every building in which the topmost floor is more than
18.3 meters but less than 30.5 meters above fire appliance access level.
(2) A hose connection shall be provided in each firefighting access lobby
(3) Dry risers shall be minimum “Class C” pipes with fittings and connections of sufficient strength to
withstand 21 bars water pressure.
(4) Dry risers shall be tested hydrostatically to withstand not less than 14 bars of pressure for two hours
in the presence of the fire authority before acceptance.
(5) All horizontal runs of the dry rising systems shall be pitched at the rate of 6.35 millimeters in 3.05
meters.
(6) The dry riser shall be not less than 102 millimeters in diameter in buildings in which the highest
outlet is 22.875 meters or less above the fire brigade pumping inlet and not less than 152.4millimeter
diameter where the highest outlet is higher than 22.875 meters above the pumping inlet.
232. (1) Where either wet or dry riser system is required, at least one riser shall be installed when the
building under construction has reached a height of above the level of the fire brigade pumping inlet
with connections thereto located adjacent to a useable staircase.
UBBL Part VII Fire Requirement:
225. (1) Every building shall be provided with means of detecting and extinguishing fire and
with fire alarms together with illuminated exit signs in accordance with the requirements as
specified in the Tenth Schedule to these By-laws
(2) Every building shall be served by at least one fire hydrant located not more than 91.5
meters from the nearest point of fire brigade access
(3) Depending on the size and location of the building and the provision of access for fire
appliances, additional fire hydrant shall be provided as may be required by the Fire Authority
227. Portable extinguisher shall be provided in accordance with the relevant codes of
practice and shall be sited in prominent positions on exit routes to be visible from all
directions and similar extinguishers in a building shall be of the same method of operation.
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9. (2) Such riser shall be extended as construction progresses to within two floors of the topmost
floor under construction and where the design height of the building requires the installation of
a wet riser system fire pumps, water storage tanks and water main connections shall be
provided to serve the riser.
237. (1) Fire alarms shall be provided in accordance with the Tenth Schedule to these By-laws.
(2) All premises and buildings with gross floor area excluding car park and storage areas
exceeding 9290 square meters or exceeding 30.5 meters in height shall be provided with a two-
stage alarms system with evacuation (continuous signal) to be given immediately in the
affected section of the premises while an alert (intermittent signal) be given in adjoining
section
(3) Provision shall be made for the general evacuation of the premises by action of a master
control.
239. There shall be two separate approved continuously electrically supervised voice
communication systems, one a fire communications system and the other a public address
system between the central control station and the following areas:
(a) lifts, lift lobbies, corridors and staircases;
(b) in every offce area exceeding 92.9 square meters in area
(c) in each dwelling unit and hotel guest room where the fire brigade system may be combined
with the public address system
241. In places where there are deaf persons and in places where by nature of the occupancy
audible alarm system is undesirable, visible indicator alarm signals shall be incorporated in
addition to the normal alarm system.
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1.3 Components of Passive Fire Protection
1.3.1 Fire Doors and Exit Sign
Passive Fire Protection System
Passive fire protection system plays a crucial role in preventing and slowing down the rate
of spread of fire and also helps protecting the occupants int the building during the event
of a fire emergency.
Emergency exit routes plays a crucial role and have to be arranged and designed precisely
to enable the occupants to safely escape the building to the open assembly point outside
the building during the event of a fire emergency.
UBBL - Section162 - Fire doors in compartment walls and separating walls
1) Fire doors of the appropriate FRP shall be provided.
3) Openings in protecting structures shall be protected by fire doors having FRP of not less
than half the requirement for the surrounding wall specified in the Ninth Schedule to these By-
laws but in no case less than half hour.
4) Openings in partitions enclosing a protected corridor or lobby shall be protected by fire
doors having FRP of half an hour.
11. UBBL - Section 173 - Exit Doors
1) All exit doors shall be openable from the inside without the use of a key or any special
knowledge or effort.
2) Exit doors shall close automatically when released and all door devices including magnetic
door holders, shall release the doors upon power failure or actuation of the fire alarm.
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Emergency exit signs play an important role as they act as an exit indication for the
occupants during a fire evacuation. These emergency exit signs has to be illuminated 24/7
to ensure the occupants in the buildings, visibility in the dark during the event of a fire
emergency. Although the electrical supply in the building would be cut off, the emergency
exit signs would still emit light to lead the occupants to the outdoor area of the assembly
point. Emergency exit signs can be found above all the fire rated door, exits, fire
staircases and doorways to ensure that the emergency exit is clea.
UBBL- Section 172-Emergency Exit Signs
(1) Storey exits and access to such exits shall be marked by readily visible signs and shall
not be obscured by any decorations, furnishings or other equipment.
(2) A sign reading ‘KELUAR’ with an arrow indicating the direction shall be placed in
every location where the direction of travel to reach the nearest exits is not immediately
apparent.
(3) Every exit sign shall have the word “KELUAR” in a plainly legible letters not less than
150mm high with the principle strokes of the letters not less than 18mm wide.
(4) All exit signs shall be illuminated continuously during periods of occupancy.
(5) Illuminated signs shall be provided with two electric lamps of not less than fifteen
watts each
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Based on ‘Guide to Fire Protection in Malaysia 2006’ :
i) An escape route should lead to a place of safety. The ultimate place of safety is the open
air outside the building, clear from the effects of the fire.
ii) In large complexes where this is not possible, it should be possible to reach a place of
reasonable safety such as protected staircase or a protected corridor from where people can
travel in relative safety to a final exit.
iii) For this to be possible, protected staircase and protected corridor must not contain
combustible materials and are designed to keep out flame, smoke an gases.
iv) The maximum permissible distance of an unprotected escape route is worked out by the
period a person exposed to fire and smoke can reasonably be expected to endure when
escaping a fire.
1.3.2 Means of Escape
UBBL By Laws Section 167- Storey Exits
1. Except as provided for in by-law 194, every compartment shall be provided with at
least two storey exits located as far as practical from each other in no case closer than
4.5 meters and in such position that the travel distance specified in the seventh
schedule to these by-laws are not exceeded.
2. The width of storey exits shall be in accordance with the provisions in the seventh
schedule to these by-laws.
Spaces
Passive Fire Components
Playroom
4 Toilets
Kitchen
Waiting Room
Office
Fire Doors ‘KELUAR’ Signs
1
4
1
2
1
1
1
1
4
2
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Several fire emergency staircases can be found in the building and are accessible for the
occupants from the above floors. It leads them to the escape route which leads them to the
outdoor assembly point through the main entrance. The emergency exit routes, have to be
kept clear at all times to prevent any obstructions during the event of a fire emergency that
may disturb the process of evacuation and cause unforeseen injuries. The emergency exit
routes have to be wide enough in accordance to the dimensions accessible for all the
occupants including the disabled to escape without interference.
1.3.3 Fire Escape Stairs
UBBL - Section 168 - Staircases
1. Except as provided for in by-law 194 every upper floor shall have means of egress via
at least two separate staircases.
3. The required width of a staircase shall be the clear width between walls but hand rails
may be permitted to encroach on this width to a maximum of 75mm.
5. Doors giving access to staircases shall be positioned that their swing shall at no point
encroach on the required width of the staircase or landing.
Figure:
14. Road
Fire hydrant is a water supply point for fireman to access to deal with buildings caught on fire.
It should not be more than 30 m away from the breeching inlet for the building, not less than
6m from the building. It should be spaced not more than 90m apart access road, while mini
mum width of access road is 6m. Fireman attaches a hose to the fire hydrant, then opens a
valve on the hydrant to provide a powerful flow of water. They can attach this hose to a fire
engine, which can a powerful pump to boost the water pressure and possibly split it into multiple
streams. If a fire hydrant is close or open too quickly, it could cause a water hammer, which may
damage nearby pipes and equipment.
(Related law: UBBL 225; M.S. 1489, 1395)
1.4 Components of Active Fire Protection
1.4.1 Fire Hydrant
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15. Although the building doesn’t exceed 18.3m in height, it is still good to have an easier access of
water for firemen to put out the fire.
(Related law: 230, M.S. 1489, 1210)
Dry Riser is formed by air vent, landing valve,
breeching inlet, and riser pipe. It transports water to
upper floors, from fire hydrant when needed, work a
form of internal hydrant for fireman. After
transporting to upper floor, a hose reel is connected
at the landing valve of the floor. Pipe length is
usually 30m, and the coverage of putting out fire is
800 square meter. Fire Hose Reels usually located at
a strategic and accessible place in a building to
provide controlled water supply to combat a
potential fire risk. A fully extended fire hose can
reach 36 meter s with 19mm diameter. Fire Hose
Reel are designed to deliver a minimum of 0.33L of
water per second. The operators are able to control
the direction and flow of water with a control nozzl
e attached to the end of the hose. All fire hose reels
come with a unique ball valve shut-off device, a
plastic or solid brass hose reel nozzle and mounting
bracket. The system pressure loss will activate the
pump ensuring adequate water flow and pressure to
provide a water jet of typically a minimum of 10
meter from the nozzle.
1.4.2 Dry Riser and Hose Reel System
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1.4.3 Fire Extinguisher
Fire extinguisher is a portable device that can be used by public, intended for
initial outbreak of fire, prevent escalation into full scale fire. It should not be
more than 20m away from potential fire hazard, like kitchen, in this building
and should be also be placed where can be easily spotted by anyone.
For this building, the main potential fire hazard is the kitchen, so a foam
type(yellow) fire extinguisher should be placed there. Other than that, there
are one dry powder type(blue) fire extinguisher for each floor. Because it
could be used by elderly, a lighter type (4kg instead of 6kg) is picked for
them.
(Related law:227)
Fire extinguisher location
17. 1.4.4 Two Stage Fire Alarm System
When manual call point or smoke detector is alerted, how two stage alarm works is
before activating the actual alarm, it will notify the control room first. The staffs may go
check and confirm the situation, then actual alarm will be activated. Two stage alarm is
picked to minimize the chance of false alarm, which will distress the occupants.
A fire alarm is a notification
appliance which uses
audible, visible to alert the
occupants of a fire. Most of
the models will produce
sound vary from 40 to 120
db. For the building, audio
visual alarm is chosen as
some of the elderly may
have hearing problems.
(Related law:
237, 239)
Fire Alarm Layout
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18. 1.4.5 Two Stage Fire Alarm System
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19. 2.0 Air conditioning system
2.1 Introduction to Air Conditioning System
Malaysia’s hot and humid climate, combine with the
risk of air pollution, air-conditioning system are
almost inevitable for a comfortable and health living.
Air conditioner removes heat in a confined place, thus
cooling the air and removing humidity in air.
2.0.1 UBBL Part III – Space, Light and Ventilation
Figure: Haze covering Kuala Lumpur city.
41. ( 1 ) Wi nd o w s a nd o p e ni ngs a l l o wing uni nte r r up te d air passage is not
necessary if the toilets is equipped with mechanical ventilation or air-conditions.
(2) In case of air-conditioning failure there should be alternative ways to introduced fresh air
into the room within half an hour.
(3) This provision apply to building with mechanically ventilated or air-conditioning.
(4) Windows and openings allowing uninterrupted air passage is not necessary if the toilets is
equipped with mechanical ventilation or air conditions.
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2.2 Literature Review for Mechanical Ventilation System
Air conditioners use refrigeration to chill indoor air, taking advantage of
a remarkable physical law: When a liquid converts to a gas (in a process
called phase conversion), it absorbs heat. Air conditioners exploit this
feature of phase conversion by forcing special chemical compounds to
evaporate and condense over and over again in a closed system of coils.
The compounds involved are refrigerants that have properties enabling them to change at
relatively low temperatures. Air conditioners also contain fans that move warm interior air over
these cold, refrigerant-filled coils. In fact, central air conditioners have a whole system of ducts
designed to funnel air to and from these serpentine, air-chilling coils.
Air conditioner have outdoor and indoor unit. Outdoor unit dissipate heat collected by
refrigerant to the outdoor environment. Indoor unit circulates and cool indoor air while
dehumidify and cleaning the air in the process.
There are two types of air-conditioning system suitable for the elderly center. Central air-
conditioning systems use ducts to distribute cooled air throughout the house. Huge spaces are
required to place all the ducting system and an air -handling unit (AHU). Split ductless
systems have an outside condenser and one to four indoor blower units mounted high on the
wall. Tubing connects these parts and circulates refrigerant. Each indoor unit cools the room
and the system can be controlled on its own. Split ductless systems need no ductwork, making
them easier to add to buildings. Split ductless system are chosen for the elderly home for its
functionality and flexibility.
Figure: Refrigerant gas used in
the air-conditioner.
Figure: Indoor unit Figure: Outdoor unit
21. 1. Evaporator is a cooling coils remove heat and humidity from the air using refrigerant.
2. Blower (or fan) circulates air over the evaporator, dispersing the chilled air.
3. Condenser is a ot coils release heat into the outside air.
4. Compressor is a pump that moves refrigerant between the evaporator and the condenser
to chill the indoor air
5. The Fan blows air over the condenser to dissipate the heat outside.
6. Filter Located in the air conditioning unit to remove particles from the air.
7. Thermostat, control system to regulate the amount of cool air that is distributed.
8. Refrigerant piping, a copper tube insulated by rubber hose transferring the refrigerant.
2.3 Basic Components of Air Conditioning System
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22. •The refrigerants used in the air-conditioning system is the compounds that have properties
enabling them to change at relatively low temperatures, such as the hydro-fluorocarbon (HCFC).
•The refrigerants circulate the compressed liquid inside the copper tube connecting the indoor and
outdoor unit.
•On the indoor unit, warm air from the room is sucked in through a grille with air filter.
•The air flows over some cooling coil-evaporator through which a refrigerant is circulating.
• It cools down the incoming air and a dehumidifier removes any excess moisture.
•Refrigerant flows through the chiller pipes absorbs heat from the air blowing past the pipes and
evaporates, turning from a cool liquid into a hotter gas.
•It carries this heat from inside the room to the outside of the building, where it gives up its heat to
the outside air.
•The coolant flows through a compressor unit and some condensing pipes, which turn it back into
a cool liquid ready to cycle round the loop again.
•In the unit outside the building, there are lots of metal plates that dissipate the heat to the
atmosphere. An electric fan blows air pass them to accelerate the process.
•Over time, the heat inside the building gradually pumps away to the outside.
2.4 Operation of air conditioning system
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23. Central air-conditioning systems distribute cooled air throughout the building through the duct
system. Copper tubing with refrigerant connect outside condenser is connected to air handling unit
(AHU), where it distribute cool air throughout the house via the duct system.
Figure: Outdoor units of central Figure: Ductwork sample diagram Air-conditioning system
Split ductless systems have an outside condenser and one to four indoor blower units mounted
high on the wall. Copper tubing connects these parts and circulates refrigerant. The tubing,
along with an electric and drain line, covered by rubber insulator, is run through about a 3-inch
hole hidden behind each indoor unit. Each indoor unit cools the room in which it's installed and
has its own control system. Split ductless systems need no ductwork, making them easier to
install.
Option 1: Central air conditioning
Option 2: Split ductless systems
Figure: Diagram of split ductless
system.
Figure: VRV system can connect
more than 1 indoor units.
2.4.1 Type of air-conditioning system for small building.
Proposed system
Split ductless system is proposed for the elderly centre because the area of air-conditioned
room is small and are separated from each other.
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2.5 Proposed Air-Conditioning System Layout Plan
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2 VRV multi-split system proposed and 1 Single split system are proposed for the selected building.
• 1 cassette type unit proposed for cafeteria and 3 cassette type indoor unit proposed for studio room. All of
which connected to a VRV multi-split system outdoor unit. Total floor area of the covered room is 159m².
The capacity needed for the system is around 30000 btu/hr.
• 2 Wall mounted indoor unit proposed for office and waiting room which connected to 1 VRV multi-split
system outdoor unit. The floor area of the space is 35m². Around 7000 btu/hr capacity needed for the system
• Playroom is installed with the single split system.
• Both indoor and outdoor unit should be mounted away from direct water and sunlight to avoid
hindrance of heat dissipation.
Positioning of air conditioning unit
2.6 Proposal for of air conditioning system
Table: cooling capacity for room size
26. Indoor Unit
Figure: Ceiling recessedcassette
(4 way) unitFigure: Wall-mounted air
conditioner
• The indoor unit is located inside the room at the location from where the air can be distributed
evenly throughout the room.
• The wall mounted indoor unit should be located at the height of about 8 to 10 feet
from the floor so that that most of the chilled air is used for cooling the room and not merely for
cooling the hot roof.
• The indoor unit should be accessibleeasilyso that one can conveniently clean the
filter every fortnight.
• The distance between the indoor and the outdoor units should be kept minimum to
increase efficiency. Maximum distance can be about 15 meters.
Outdoor Unit
Figure: VRV system
outdoor unit
• The outdoor unit should be located in the well ventilated space so that the air can
flow freely over the compressor and the condenser.
• The surface on which the outdoor unit is to be installed should be rigid enough to
avoid its vibration and noise
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27. 3.0 Mechanical Ventilation System
3.1 Introduction to Mechanical Ventilation System
The selected building has a main structure with 2 segregated blocks to accommodate office
and play room respectively. This would mean there would be several air handling units in each
different units places if all the ductwork and equipment want to be hidden from the users. Air
supply system is proposed as the main service in the building as this system can guarantee a
consistent supply to the user without using air -conditioning. As this building will be mainly
used by the old folks, long exposure to air-conditioning is not good for their health. However,
there are some except to the choice of utility. In the area such as kitchen where there is
unwanted smell or odours, extract system will be applied to keep the odour away from
spreading to other spaces. This Mechanical ventilation system can provide fresh air together
with the ceiling fan or other standalone fan to create air movement, to achieve thermal comfort
level. Comparing this to extract system, indoor air still can be replenished
Example of supply
ventilation system, air is
extract from an air inlet
then filtered before
supplying to the indoor
spaces.
U B B L Pa rt III S p a c e Lig h t a n d Ve n t ila t io n
41. ( 1 ) Wi nd o w s a nd o p e ni ngs a l l o wing uni nte r r up te d air passage is not
necessary if the toilets is equipped with mechanical ventilation or air-conditions.
(2) In case of air-conditioning failure there should be alternative ways to introduced fresh air
into the room within half an hour.
(3) This provision apply to building with mechanically ventilated or air-conditioning.
(4) Windows and openings allowing uninterrupted air passage is not necessary if the toilets is
equipped with mechanical ventilation or air conditions.
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28. 3.2 Literature Review for Mechanical Ventilation System
Ventilation is necessary in buildings to remove ‘stale’air and replace it with ‘fresh’ air.
A good ventilation will ensure the comfort of the users and it also:
• Help replenishing the air in a room, also the air inside to be ‘filtered’, reducing the
accumulation of bacteria, dust, smoke, and odours as well as the moisture in air.
• Moderate internal temperature to improve thermal comfort of the occupants by
creating air movement.
Ventilation in building is categorized into two types, which is natural and mechanical
ventilation. In a hot and humid country like Malaysia, natural ventilation is preferable to
mechanical ventilation as it will have lower operational and maintenance cost. Using
mechanical means to achieve comfort would be highly unsustainable to the environment in
the long run. However there are conditions where natural air cannot reach to the interior
spaces or the stale air inside the room cannot escape effectively. It is where the mechanical
ventilation system will come into place.
Example of air handling unit.
Image source:
https://engfac.cooper.edu/pages/mel
ody/uploads/i/AHUschemwithrecirc_
728x431.jpg
A mechanical ventilation system mainly uses powered fans or blowers, also known as ‘air
handling units (AHU), connected to ductwork within the building to supply fresh air to and
extract air from the interior. The advantage of mechanical ventilation over natural ventilation is
that, the occupants can get to decide the kind of air quality they want. For instance, by
installing proper equipment such as humidifier or dehumidifier in the ventilation systems, a
desired air humidity level can be achieved.
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29. 3.3 Component of Mechanical Ventilation System
3.3.1 Air Handler
Air Handler is a blower, or a mechanism that contains a fan
that serves to circulate the air throughout the building’s
ductwork. There are mainly three types of fan:
Mechanical
Fan
• Propeller Fan does not create much air pressure and has
limited effect in ductwork. Ideal for use at air openings in
windows and walls.
Reason of selection: This fan will be suitable to apply in small
area such as the toilet.
• Axial Flow Fan can develop high pressure and is used for
moving air through long sections of ductwork.
Reason of selection: The fan is integral with the run of ducting
and does not require a base. This fan will be applied
• Centrifugal Fan can produce high pressure and has the
capacity for large volumes of air. Most suited to larger
installations such as air conditioning systems. It may have one
or two inlets. Various forms of impeller can be selected
depending on the air condition. Variable impellers and pulley
ratios from the detached drive motor make this the most
versatile of fans.
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30. 3.3.2 Filter
The filter is generally incorporated together with the fan which is within the air handling unit.
Depending on the requirement of the occupants and the activities, specific type of filter will
be used among the 3 which is:
• Dry filter generally use materials such ascotton wool, glass fibre, cotton fabric, treated
paper, foamed polyurethane as the cleaning medium. The contaminant are to be collected in
the filter medium consistently to ensure a good indoor air quality. The efficiency of the filter
depends largely upon the area of medium offered to the air stream and for this reason the
filter can be arranged in a ‘V’ formation which increases the area.
• Reason of selection: Dry filter will be the selection of type as it is suitable to be installed in
the small size building. Specifically, panel type filter will be chosen together with the
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31. • Viscous filter, is used when filter of oil or industrial chemical is needed. It has a large dust-
holding capacity and are therefore often used in industrial areas where there is a high
degree of atmospheric pollution. The filter medium is coated with a non- inflammable,
non-toxic and odourless oil, which the contaminants adhere to as they pass through the
filter. There are two types of viscous filters such as cell type and automatic type.
• Electrostatic filter, in which the contaminants are positively charged with electricity and
collected on negative earthed plates. These types of filters have three main components:
ionizer, metal collector and electrostatic power pack. The various air contaminants are
given a positive electrostatic charge by an ionizer screen which is the first part of the filter.
• The screen consists of a series of fine wires possessing an electrostatic charge produced
by a direct current potential of 13 kV. • The wires are spaced alternatively with rods or
tubes which are at earth potential.
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32. 3.3.3 Air inlet/ outlet
Openings that allow flow of air inside and outside of the building. There are mainly three
types of them, mainly:
• Grilles is any air outlet/ inlet either is square, rectangle or other
shape that is made up of louvers, used to deflect the air.
• Register, similar to grilles its louvre can be adjusted, thus enable
the amount of air flow to be adjusted.
• Diffuser usually used to mount on the ceiling, the air equally
diffusing to the side also the fresh air equally mixed within the
room.
Reason of selection: It is selected so that the air can evenly
distributed from ceiling.
3.3.4 Terminal units
Terminal units is an electrical automated damper to control the
amount of air which is delivered to a room or region. It consist of 1
or more blade which can be used to control the amount of air flow
through a duct.
It is regulated by a thermostat which could sense the temperature and determine the
amount of air flow to the interior.
3.3.5 Flexible non-metallic air duct
A standard air duct applied in many public building, it is the main
passage way for air-channelling throughout the system. Its insulation
allow the temperature to maintain in an optimum level when
channelling.
3.3.6 Thermostat
It is a component which senses the temperature of a system so that
the system’s temperature is maintained near a desired set point.
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33. 3.4 Supply Ventilation System
The system works by pressurizing the interior with the supply of air forcing out the stale
air in the room. When the current is switched on, the fan rotation will then suck in the
outdoor air. The air will be filtered by a medium before it reaches the room and then pass
by the cooling coil to lower down the air temperature so that the fresh air that is
providing to the user is comfortable. To solve the unwanted air distribution to the whole
area, the installation of terminal unit will help regulate the amount of air flow wanted
depending on the user needs and the room temperature. Thermostat is
work together with terminal unit to control the amount of air flow into the building
produced from mechanical ventilation system. Once the air is filtered and cooled, it will
supply into the rooms. In the foreign country will have both cooling and heating coil for
allowing the occupant to adjust the room temperature depending on the season.
Spaces in the elderly center that requires Supply Ventilation System are the studio room
that located at the first floor as these spaces accommodate long hour activities such as
the studio room for the elderly people to do their indoor hobbies.
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34. As mentioned earlier as the building has a segregated room units, this system with air
handling unit is proposed to be installed in the areas that has relatively larger room area
which are located in the main building. Its main function be supplying of fresh air instead of
cooling the temperature as air-condition is installed in every room of the building, however,
old folks is prone to sickness to if exposed to much of cool conditioned air, that’s why this
system is proposed as the substitution for air-conditioning.
Curtain air is another supply system that will be installed as well at the door way of the
dining area. Beside these area like kitchen and toilet will be proposed with extract system to
remove the unwanted smell.
Curtain air works by blowing the wind from top
of the entrance to downward forming a natural
barrier from outside hot air, dust and insect from
entering to the interior space. This air barrier will
ensure the room is cool and comfortable.
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35. 3.5.2 Extract Ventilation System
Kitchen stove exhaust hood
An exhaust hood, extractor hood, or range hood is a device containing a mechanical fan that
hangs above the stove or cooktop in the kitchen. It removes airborne grease, combustion
products, fumes, smoke, odours, heat, and steam from the air by evacuation and filtration of
the air. It is proposed to be applied in kitchen area.
Extract fan in toilet
This exhaust fan works together with the grilles, serves to remove the stink air in the toilet.
It is electrically powered, switched on once the bathroom light is switched on.
Extract Ventilation Systems provide continuous ventilation. The centralized systems draw
moisture-laden air from multiple wet rooms of a property.
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36. 3.6 Proposed Ventilation System Plan for Elderly Center
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37. 4.0 Mechanical Transportation System
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4.1 Introduction to Mechanical Transportation System
Mechanical transport systems are the systems that carries people or goods horizontally or
vertically from floors to floors or long distance in a building.
The aim of the mechanical transport is to save user’s energy from climbing, walking and
running & assist disabled or elderly around the building. It also assists disabled on a
wheelchair to move easily and safely around and ease the transportation of heavy goods that
carry from floors to floors. Example of mechanical transport systems, are lifts or elevators
and escalator.
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4.2 Literature Review
MS 2021-1, Safety rules for the construction and installation of lifts –
Part 1 : Electric lifts.
5.2.2.2.1 Emergency doors shall be capable of being self-closing.
5.7.3.2 If there is an access door the pit, other than the bottom terminal landing door, it
shall comply with the requirements of 5.2.2.
MS 81-1:2012-Clause 15.4.1. – A notice bearing the following minimum inscription:
“BILIK JENTERA LIF BAHAYA DILARANG MASUK TANPA KEBENARAN”
should be provided.
UBBL 1984
124 – For all non-residential buildings exceeding 4 stories above or below the main
access level at least one elevator shaft be provided.
152 (1) – Every opening in an elevator shaft or elevator entrance shall open into a
protected lobby unless other suitable means of protection to the opening to the
satisfaction of the local authority is provided. These requirements shall not apply to
open type industrial and other special building as may be approved by D.G.F.S.
153 (1) – All elevator lobbies shall be provided with smoke detectors
155 (2) – If mains power is available all lifts shall return in sequence directly to the
designated floor, commencing with the fire lifts, without answering any car or landing
calls, overriding the emergency stop button inside the car, but not any other emergency
or safety devices, and park with doors open.
155 (3) – The fire lifts shall then be available for use by the fire brigade on operation of
the fireman’s switch.
155 (4) – Under this mode of operation, the fire lifts shall only operate in response to
car calls but not to landing calls in a mode of operation in accordance with by-law 154.
Emergency mode of operation in the event of mains power failure.
154 (1) – On failure of mains power of lifts shall return in sequence directly to the
designated floor, commencing with the fire lifts, without answering any car or landing
calls and park with doors open.
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Elevator Regulation
-The minimum internal space of elevator, allowing for one
wheelchair passenger alone, are 1.00 m x 1.30 m
-The door opening should not be less than 0.80 m.
-The inside of the elevator should have a handrail on three
sides mounted 0.80 to 0.85 m from the floor (figure 2).
-The maximum tolerance for stop precision should be 20mm.
-For ease of reach of the control panel, it must be mounted
0.90 m to 1.20 m from the floor.
-Control buttons should be in an accessible location and
illuminated. Their diameter should be no smaller than 20mm.
-Tactile numerals should be placed on both sides of the door
jambs at an approximate height of 1.50 m to help a lone
sightless passenger to identify the floor reached (figure 4).
-The elevator hall signal should be placed at an approximate
height of 1.80 m (figure 4).
-The elevator should signal arrival at each floor by means of a
bell and a light to alert sightless and hearing-impaired
passengers simultaneously.
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Above Ground Cylinder MRL Hydraulic elevators are usually used for low-rise
applications of 2 to 8 stories such as apartment, office, etc.
The operational components are located in the hoistway, eliminating the need for a
machine room. Hydraulic elevators are supported by a piston at the bottom of the
elevator which pushes the elevator upwards as electric motor forces oil or another fluid
into the piston. The elevator descends as a valve released the fluid from the piston.
It is suitable for elderly home because low-rise buildings typically use hydraulic elevator and has
lower initial cost.
Advantages of Above Ground Cylinder MRL Hydraulic elevator:
• Removal of the superstructure machine room which allows better utilization of the space and
lower installation cost.
• Low installation & lower maintenance cost.
• Longer useful life because the elevator’s system function in hydraulic oil.
• The possibility of emergency lowering if the electricity is interrupted.
• Single time 3 phase power used in up – direction only.
• Safety, comfort and low noise levels.
• Eco-friendly - Hydraulic fluid undergoes 100% recycling after 5-10 years of operation.
• In earthquake endangered areas, the hydraulic elevator has proven itself to be clearly the safer
option. Due to the threat presented by swinging counterweights and also because the car is
suspended from the top of the hoistway
4.3 Above Ground cylinder MRL(Machine Room Less )- Hydraulic Elevator
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4.3.1 Component of System
• Cylinder, is a device that transfers fluid or
electrical energy into mechanical energy.
The actuator could be piston because it
moves upwards and downwards.
• Valve, let Liquid move out of the system,
keep the pressure low when it’s open and
it increases pressure when it’s closed.
• Pump, main function of a pump is constantly
pushing Liquid into the cylinder to lift the
elevator.
• Propeller Fan does not create much air
pressure and has limited effect in
ductwork. Ideal for use at air openings in
windows and walls.
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4.3.2 Operation System
A. Pump forces fluid from the tank into a pipe leading to the cylinder.
B. As the fluid collects in the cylinder, it pushes the piston upwards, lifting the elevator
car.
C. When the car arrives near the floor, the control system sends a signal to the electric
motor to gradually turn off the pump. With the pump off, there is no more fluid
flowing into the cylinder, but the fluid that is already in the cylinder remains inside
which make piston rests on the fluid so that the car stays on the floor.
D. To lower the car, the elevator control system sends a signal to the valve. The valve is
operated electrically by a basic solenoid switch (Actuator). When the solenoid opens
the valve, the fluid that has collected in the cylinder will flow out into the fluid
reservoir. The weight of the car and the cargo pushes down on the piston, which drives
the fluid into the reservoir. The car gradually descends.
E. To stop the car at a lower floor, the control system closes the valve again.
Operation of System
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4.4 Proposed Hydraulic Lift Plan &Section Drawing for Elderly Center
44. Conclusion
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In conclusion, the building services in the bungalow we designed is both sufficient and
efficient. Most of the components adhere to their basic requirements and obeyed the
Uniform By-Law codes and the MS 1525 requirements.
Throughout this project, we manage to gain our knowledge on knowing how to identify
the different types of systems and components involved. The types of building services
are the fire protection system, mechanical ventilation and air-conditioning system and
mechanical transportation system. We also then learned how to identify the estimated
dimensions of the components and the spaces required for all the different types of
components.
45. Fire Protection List of Reference:
-https://www.fpoa.bc.ca/Association/Annual%20Seminar/2012/Speaker%20Files/Sean
%20Tracey/Two%20Stage%20Alarm%20presentation.pdf
-http://abodefireextinguisher.com/
-http://www.infectioncontroltoday.com/articles/2000/10/an-introduction-to-fire-safety.aspx
-http://www.lifesafetyservices.com/active-vs-passive-fire-protection-2/
Air Conditioning List of Reference:
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http://www.consumerreports.org/cro/central-air-conditioning/buying-guide.htm
-http://home.howstuffworks.com/ac1.htm
- https://www.energystar.gov/products/heating_cooling/air_conditioning_room
- http://www.brighthubengineering.com/hvac/45249-indoor-and-outdoor-installation-of-split-
air-conditioners-deciding-the-location/
- http://actoday-fl.com/how-air-conditioning-works.htm
- https://www.daikin.com/products/ac/lineup/split_multi_split/index.html
46. Mechanical Transport list Reference:
-http://siteexplorer.info/domain/rockmill.co.uk
- http://discoverykids.com/articles/how-do-elevators-work/
-http://www.electrical-knowhow.com/2012/04/basic-elevator-components-part-
one.html
-http://www.un.org/esa/socdev/enable/designm/AD2-02.htm
-http://www.schumacherelevator.com/elevators/hydraulic-elevators/holeless-
machine-roomless-mrl-hydraulic-elevators.aspx
Mechanical Ventilation List of Reference:
-http://beodom.com/en/education/entries/taking-care-of-the-air-you-breathe-or-all-about-ventilat
-http://www.hometips.com/how-it-works/ventilation-systems-exhaust.html
-https://en.wikibooks.org/wiki/Building_Services/Ventilation/Mechanical
-https://www.designingbuildings.co.uk/wiki/Mechanical_ventilation_of_buildings
-https://www.youtube.com/watch?v=fqvo7bSr6t8
-http://www.slideshare.net/nosuhaila/lec-7-air-flow-rate
-http://www.house-energy.com/House/SupplyVsExhaust.html
-http://www.ventilation-system.com/cat/typical-smoke-control-system-solution/
-http://uol-ventilation.weebly.com/mechanical.html
-https://www.scribd.com/doc/37904241/Ubbl-Part-III
-http://www.slideshare.net/NooruleInieOsman/ventilation-system-25941705
-http://www.lotusfilters.com.au/blog/your-kitchen%E2%80%99s-exhaust-system-explained-
diagram
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