Building Services Report

Building Services Systems
for
Old Folks Home
Building Services
BLD 60903/ ARC 2423
Prepare by:
Amos Tan Chi Yi 0318330
Neoh Jia Wen 0318228
Nge Jia Chen 0317738
Nor Syarianna Khairul Azhar Neo 0318236
Tang Ju Yi 0317735
Wong Carol 0317742
Tutor: Mr. Siva

Building Service Systems Report | 2 | P a g e
1 Abstract
2 Introduction to the building
3 Fire Protection System:
3.1 Active Fire Protection System
3.1.1 Literature Review: Active Fire Protection System
3.1.2 Proposed Active Fire Protection System :
- A. Automatic Fire Detection and Alarm Systems
- B. Fire Suppression Systems
3.2 Passive Fire Protection System
3.2.1 Literature Review: Passive Fire Protection System
3.2.2 Proposed Passive Fire Protection System:
-A. Fire Escape
-B. Fire Compartmentation
4 Air Conditioning System :
4.1 Introduction to Air-Conditioning
4.2 Literature Review: Centralized Air-Conditioning
4.3 Air Conditioning By-Laws
4.4 Proposed Air Conditioning System:
-Zoned Packaged Air Cooled Centralized Ducted Air Conditioning
Table of content

5 Mechanical Ventilation System :
5.1 Introduction to Mechanical Ventilation
5.2 Literature Review: Supply Ventilation System
5.3 Mechanical Ventilation By-Laws
5.4 Proposed Mechanical Ventilation System:
-Supply Ventilation System
6 Mechanical Trasnportation System :
6.1 Introduction to Mechanical Transportation
6.2 Literature Review: Hydraulic Elevator System
6.3 Mechanical Tranposrtation By-Laws
6.4 Proposed Mechanical Ventilation System:
-Hole-Less Machine Less Hydraulic Elevator
7 Summary
8 References
9 Appendix

The following proposal documents our journey of getting know building services in real life.
We were assigned to perform an analysis and propose buildings services in an elderly center.
The system that has been analyzed include fire protection system, air conditioning system,
mechanical ventilation system and mechanical transportation system.Through the study , we
gained insight related to the function and operation of the building service components which
we integrate it into the elderly center.
The analysis is documented and translated via detailed analysis with explanation on how the
building services components function and why they are suiteable for the elder center. Each of
the system are compareds with UBBL Law requirement in order to obtain better undestanding
of the regulations applied to different services.
1 Abstract

Elderly centre of Taman Kanagapuram
Location: Taman Kanagapuram, Jalan Klang Lama, 12, Jalan 18/16, Seksyen 18, 58200
Selangor
Area: 906 sqm
An elderly centre for 40-50 occupants is located in aquiet and old residential area- Taman
Kanagapuram, Old Klang Road.The project aims to create a “ neighbourhood atmosphere”- a
place with a balance between a “community “life stimulating the exchange and the
relationship, but at the same time, preserving the necessary privacy of each occupant.
Load-bearing ceilings and walls are made of concrete while all other structural elements are
wood. The three-storey building consists of two wings arranged around a semi-public “village
2 Introduction to the Building

square”, designed to host various events. This is also the location of the open cafe, gaming
space as well as an open, tended atrium.
The front wing houses the service areas such as dental, saloon, cafe and reception. Emergency
room is located on the ground floor and nearby office ,easily accessed, making work process
highly efficient. The back wings designed to house quiet spaces such as caretaker
accomodation, computer lab and reading area. Special attention has been paid to ensure
sufficient natural light floods the entire building and in the same time occupant can enjoy the
view.
Ground floor plan

Second floor planFirst floor plan

3.1 Active Fire Protection System
3.1.1 Literature Review : Active Fire Protection
Active fire protection systems are installed for the express purpose of positively changing the
course and resulting outcome of a fire in a building. Active fire protection systems can be
broadly classified into the following four different groups:
1. Automatic Fire Detection and Alarm Systems
Related System: -Ionization Smoke Detector
-Heat Detector
-Two-Stage Fire Alarm System
-Fire Alarm Bell
-Manual Call Point
Fires predictably produce products of combustion including smoke, high tempertaures,
and radiant energy that can be identified by sensors placed throughout the building.
Once smoke levels exceeding a certain threshold are measured inside a detector, a
signal can be sent to an alarm system that notifies occupants in the building and/or the
fire department. Although fire detection and alarm systems can reduce the time it takes
for people to leave a building or how long it takes the fire department to arrive, they
do not slow the growth of the fire or reduce the production of smoke, thus the fire
hazard is still present.
2. Automatic Fire Suppresion Systems
Automatic fire suppresion systems apply a fire-suppressing chemical such as water,
carbon dioxide, dry chemical, or foam to a fire without the need for human
intervention, resulting in a reduction in the hazard to occupants, structures, and
contents. Water flow in a pipe due to the opening of a sprinkler can be monitored and
used to signal an alarm of fire, thus automatic fire suppresion systems both warn of a
fire and control it, thereby reducing the hazard.
3 Fire Protection System

3. Manual Fire Suppression Systems
Related System:- Multipurpose Dry Chemical Fire Extinguisher
-Dry Riser System
-Hose Reel System
-Fire Hydrant
In large or tall buildings, it is difficult and time consuming for the fire department to
pull hose lines up stairs or across floors. To assist building occupants and fire fighters
in quickly applying water to a fire, standpipes ( vertical or horizontal pipelines ) can
be connected to a water supply to provide water where hose lines off fire trucks cannot
easily reach. Because both the fire department must be present and valves opened,
standpipes do not automatically control a fire. Although fire extinguishers and fire
hoses are used against unwanted fires, they require a willing human operator to be
present, so are another example of manual suppresion.

3.1.2 Proposed Active Fire Protection System
Unlike passive fire protection, active fire protection systems interact with their surroundings
e.g. by operating fans for smoke extraction, operating a fire sprinkler to control or extinguish
a fire, or opening a vent to allow assisted natural ventilation. The first stage of active fire
protection is to detect the fire, by detecting heat, smoke or flames (an automatic fire alarm
system is commonly used to trigger most active systems), this then automatically operates the
active systems (extraction fans etc).
Active systems are particularly useful in larger buildings where it is difficult to ventilate
central areas through natural openings such as windows, smoke and heat extraction systems
are often used. Their purpose is improve the visibility in the building so that occupants can
make their exit and to prevent flashover. Using active fire protection systems has some
benefits such as permitting design freedoms and encourage innovative, inclusive and
sustainable architecture.
The following are the introduction and function of the proposed active fire protection system
to be implemented in the Old Folk’s Home:

A. AUTOMATIC FIRE DETECTION AND ALARM SYSTEMS
i) FIRE DETECTORS
According to UBBL 1984,
225. Detecting and extinguishing fire.
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.
(1) Ionization Smoke Detectors
A smoke detector transmits a signal to the control unit when the concentration of
airborne combustion products reaches a predetermined level. Ionization smoke
detectors are sensitive to the presence of ions, which are electrically charged particles
produced by the chemical reactions that take place during combustion. Ionization
smoke alarms can quickly detect the small amounts of smoke produced by fast flaming
fires, such as cooking fires or fires fueled by paper or flammable liquids.

(2) Heat Detectors
A heat detector transmits a similar signal when the temperature reaches a
predetermined level or when there is an abnormal rate of temperature rise. Due to the
nature of kitchens they are quite regularly filled with smoke, so a kitchen is not
suitable to locate a smoke detector. Optical and ionization smoke detectors in such an
environment will cause false alarms but this can be avoided by using heat detectors.
These heat detectors will detect abnormally high temperatures or rapid rises in
temperature and alert the building occupants of potential fire in kitchen.

ii) FIRE ALARMS
237. Fire alarms.
1. Fire alarms shall be provided in accordance with the Tenth Schedule to these
By-laws.
2. All premises and building with ground floor area excluding car park and
storage area exceeding 9290 square metres or exceeding 30.5 metres in height
shall be provided with a two-stage alarm 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.
258. Command and control centre.
Every large premises or building exceeding 30.5 metres in height shall be
provided with a command and control centre located on the designated floor and
shall contain a panel to monitor the public address, fire brigade communication,
sprinkler, waterflow detectors, fire detection and alarm systems and with a direct
telephone connection to the appropriate fire station by-passing the switchboard.
(3) Two-stage fire alarm system
In the elderly centre, a distinct alert signal can first advises the staff of the fire
emergency. After the staff investigating the source of alarm, if a fire exists, an
alarm signal will be activate or the caretaker are allowed to have time to evacuate
the elderly. On the other hand, if it is determined that the alert is a false alarm,
staff can silence the coded alert signal and reset the system. It is used in the elderly
centre to prevent undue distress to the occupants. This is particularly important
because evacuation assistance may be required.

(4) Fire Alarm Control Panel (FACP) – Conventional Panel
A Fire Alarm Control Panel (FACP) is an electric panel that is the controlling
component of a fire alarm system. The panel receives information from
environmental sensors designed to detect changes associated with fire, monitors
their operational integrity and provides for automatic control of equipment, and
transmission of information necessary to prepare the facility for fire based on a
predetermined sequence. Conventional panels have been around ever since
electronics became small enough to make them viable. They are no longer used
frequently in large buildings, but are still used on smaller sites. It is suitable for the
elderly centre where it is a small building with only 500sq.m floor area.
Figure 8: Fire alarm control panel

(5) Fire Alarm Bell
Fire alarm bell uses audible stimuli to alert the occupants during a fire or other
emergency condition requiring action. The minimum sound level of a sounder
device should be 65dB(A) or 5dB(A) above a background noise (if lasting more
than 30 seconds) and the maximum sound level should not exceed 120dB(A).
The elderly centre is located in between residential area whereby the fire alarm
bell should be located carefully. The maximum sound pressure level allowable at
the minimum distance when combining ambient noise with that of the
notification appliance devices should not exceed 110 dB.
Figure 9: Fire alarm bell

(6) Manual Call Point
Manual fire alarm call points for fire alarm systems are devices that enable
people to raise a fire alarm in the event of a fire incident by pressing or
breaking an element to activate the fire alarm system. It should be installed at a
height of 1.2m above floor level at exit routes and at the entry floor landings of
staircases. It should be placed with a maximum distance of 45m apart or 25m
apart for disabled person.

B. FIRE SUPPRESSION SYSTEMS
(i) FIRE EXTINGUISHER
227. Portable extinguishers.
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.
(7) Multipurpose Dry Chemical Fire Extinguisher
Class A fire
Solid matters forming glowing reside. Wood, paper, textile, cloth, rubber, plastic etc.
Class B fire
Flammable liquid fires. These can be fires where cooking liquids, oil, gasoline,
kerosene, or paint have become ignited.
Class C fire
Fire extinguishers with a Class C rating are suitable for fires in “live” electrical
equipment. Computers and electricity apparatus can be found in the computer lab of
elderly centre.
Dry Chemical fire extinguishers extinguish the fire primarily by
interrupting the chemical reaction of the fire triangle. Today's
most widely used type of fire extinguisher is the multipurpose dry
chemical that is effective on Class A, B, and C fires. This agent
also works by creating a barrier between the oxygen element and
the fuel element on Class A fires.
Figure 1: Dry chemical fire
extinguisher

Figure 2: A fire extinguisher
should be located at 5 feet above
the floor.
Figure 3: Fire extinguisher and
fire extinguisher signage

(ii) DRY RISER SYSTEM
230. Installation and testing of dry rising system.
1. Dry rising systems shall be provided in every building in which the topmost floor is
more than 18.3 metres but less than 30.5 metres above fire appliance access level.
2. A hose connection shall be provided in each firefighting access lobby.
3. Dry risers shall be of 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 house 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 metres.
6. The dry riser shall be not less than 102 millimeters in diameter in buildings in which
the highest outlet is 22.875 metres or less above the fire brigade pumping inlet and
not less than 152.4 millimeters diameter where the highest outlet is higher than
22.875 metres above the pumping inlet.
(8) Dry Riser
A dry riser is a system of pipes and valves that extend to the upper storeys of an occupied
building. This system is based on an inlet (‘inlet breeching’ on the outside wall of a
property) and a series of outlets (Gate or Landing Valves) at each floor (internally) of a
property which are principally located in lobbies, fire shafts or stairwells. The dry riser
systems pipes are filled with compressed air which is released in an emergency to let
water flow through the pipes. The outlet points are positioned on the upper storeys
allowing firefighters easy access to water in the event of a fire. Dry risers have to allow fire
engine access within 18 m of the dry riser inlet box. It is located at the fire resistant shaft
which is the fire escape staircase in the elderly centre.

Dry Riser Inlet Cabinet and Dry Riser Outlet Cabinet
The inlet cabinet or breeching inlet should be positioned as closely as possible to the rising
main in order to reduce the pressure loss and within easily accessible reach of the attending
fire appliance which should be in un-obscured sight of fire crews and no more than 18 metres
away from the nearest vehicular access.
Figure 15: Dry riser main
Figure 17: Dry riser inlet with glass
front is designed to be broken during
an emergency.
Figure 18: Dry riser outlet should be
installed with it’s lowest point at
750mm above floor level.
Figure 16: Dry riser that connected to
a pressurized water source by
firefighter

(iii) HOSE REEL SYSTEM
According to MS 1489,
4.2.2 Siting
Hose reels should be sited in prominent and accessible positions at each floor level adjacent
to exits in corridors on exit routes, in such a way that the nozzle of the hose can be taken
into every room and within 6 m of each part of a room, having regard to any obstruction.
Where heavy furniture or equipment might be introduced into a room, the hose and nozzle
should be capable additionally of directing a jet into the back of any recess formed.
According to MS 1488,
-The rubber hoses be a minimum of 30 m in length
-Size of Hose Reel Pipe is 50mm diameter with a 25mm feed and the material is Galvanised
Steel which is the Medium Grade Class B for above ground
(9) Swinging arm hose reel
A hose reel designed to be mounted on wall and which is capable of being swung through an
arc of approximately (180) in a horizontal plane. It allows hose to be guided to any direction.
Figure 19: Swinging arm hose reel Figure 20: Top view of swinging arm
hose reel

Elderly
Centre
FIRE HYDRANT
225. Detecting and extinguishing fire.
2. Every building shall be served by at last one fire hydrant located not more than
91.5metres from the nearest point of fire brigade access.
(10) Fire Hydrant
A fire hydrant can be found located 50m away from the elderly centre. Therefore, it is not
necessary to propose a new fire hydrant. Fire hydrants allow firefighters to access a local
water supply quickly. A fire truck will usually haul enough water to allow firefighters to
begin to fight a fire while hoses are being connected to the nearest fire hydrant. Firefighters
usually have to use a special pentagonal wrench to remove the valve covers on a fire hydrant.
Once the covers are removed, firefighters can attach hoses to the valves. They then open
a valve that allows water to flow through the hydrant into the hoses. Fire hydrants can supply
a large volume of water where water is pumped through hoses to the fire truck. The water is
pressurized and divided into several streams to supply water to multiple fire hoses at once.
Figure 21: Google street view of Jalan 18/16, Taman Kanagapuram.

3.1 Passive Fire Protection System
3.1.1 Literature Review : Passive Fire Protection
Built facilities may be provided fire protection either by building in fire safety measures or by
means of early control through detection and extinction methods. Built-in measures
introduced through resistance-to-fire and reaction-to-fire improvement provisions may be
classified as passive fire protection, while the latter may be termed active fire protection.
Active fire protection systems function by reacting to conditions caused by a fire such as heat,
smoke or light to impede the fire process. Active and passive fire safety provisions are
complementary, not competitive.
The concept of passive fire protection is based on the principles of:
 Controlling likelihood of ignition.
 Containment of fire and it effects within an area – compartmentation, opening
protection like fire doors and wired glass, fire stops, dampers, etc.
 Conferring fire resistance to the structure and building elements for a specified time
period – structural fire protection achieved with fireproofing materials such as sprayed
film intumescents, gypsum-based plasters and cementitious product, mineral wool
wraps and insulation, cladding or encasing in concrete.
Three major roles in building fire safety by:
 Directly influencing the development of fire (by providing fuel or by controlling
ventilation).
 Inhibiting the growth or spread of fire itself, or the spread of the products of fire.
 Assisting the people affected or potentially affected by the fire to remove themselves
from a hazardous location, or to gain access to fight the fire.

Passive fire protection can be classified into the following :
1. Architectural Configuration ( Floor Area, Architectural Layout )
Related System : -Fire Evacuation Route
-Escape Travel Distance
-Assembly Point
2. Designed openings and their treatment (doors, windows and interstitial spaces in
separating elements)
Related System : -Fire Rated Door
-Fire Staircases
-Emergency Exit Signage
-Emergency Light

3.1.2 Proposed Passive Fire Protection System
Unlike passive fire protection, active fire protection systems interact with their surroundings
e.g. by operating fans for smoke extraction, operating a fire sprinkler to control or extinguish
a fire, or opening a vent to allow assisted natural ventilation. The first stage of active fire
protection is to detect the fire, by detecting heat, smoke or flames (an automatic fire alarm
system is commonly used to trigger most active systems), this then automatically operates the
active systems (extraction fans etc).
Active systems are particularly useful in larger buildings where it is difficult to ventilate
central areas through natural openings such as windows, smoke and heat extraction systems
are often used. Their purpose is improve the visibility in the building so that occupants can
make their exit and to prevent flashover. Using active fire protection systems has some
benefits such as permitting design freedoms and encourage innovative, inclusive and
sustainable architecture.
The following are the introduction and function of the proposed passive fire protection system
to be implemented in the Old Folk’s Home:

A. ARCHITECTURAL CONFIGURATION
i) FIRE EVACUATION ROUTE
Section 178: Exits for institutional and other places of assembly
In buildings classified as institutional or places of assemble, exits to a street or large open
space, together with staircases, corridors and passages leading to such exits shall be located,
separated or protected as to avoid any undue danger to the occupants of the place of assembly
from fire originating in the other occupancy or smoke therefrom.
Section 169: Exit route
No exit route may reduce in width along its path of ravel from storey exit to the final exit.
(1) Evacuation Route
Fire evacuation route is designed to provide a fast and efficient escape during an event
of fire. Two fire staircases are provided for means of escape in a distress situation.
One of the staircases is located near the back of the building while another one is
closer to the front.
Means of escape is a safe evacuation route to transport a building occupant from a
distressed situation to safe zones (outside of the building). Such protected areas or safe
zones should be constructed using non-combustible or extremely durable materials.
The fire evacuation route should be well designed to provide a fast and efficient means
of escape in a distress situation. There are two fire staircases in the building to provide
means of escape during an event of fire. The emergency exit signage should be
provided within the building as reference to building occupants at any place and floor
they are located at.

Section 165:
(3) In the case of individual rooms which are subject to occupancy of not more than six
persons, the travel distance shall be measured from the doors of each rooms: provided that the
travel distance from any point in the room to room door does not exceed 15 metres.
(4) The maximum travel distance to exits and dead end limits shall be specified in the Seventh
Schedule of these by-laws.
Section 174:
(1) Where two or more storey exits are required they shall be spaced at not less than 5 metres
apart measured between the nearest openings.
(2) Escape Travel Distance
With thoughtful consideration, the building provides good travel distance design to
prevent human traffic congestion when an event of fire occurs.
(3) Assembly Point
The assembly point is the final destination of the fire escape route. Upon escaping
from the building interior to the building exterior via escape staircase and emergency
exits, building occupants must seek refuge in an open area free from hazards of a fire
outbreak. This area must be large enough to accommodate the crowd, and serves as a
convenient location to conduct headcounts and miscellaneous rescue process.The
Figure 1: Travel distance from any point of
room to room door does not exceed 15m.

assembly point of the building is located at the car park, which is a large open space in
front of the building.

B. COMPARTMENTATION, DESIGNED OPENINGS AND ITS’ TREATMENT
i) FIRE RATED DOOR
Section 162: Fire doors in compartment walls and separating walls
(1) Fire doors of appropriate FRP shall be provided.
(2) Openings in compartment walls and separating walls be protected by a fire door having a
FRP in accordance with the requirements for that wall specified in the Ninth Schedule to
these Bylaws.
(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
Bylaws 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-hour.
(5) Fire doors including frames shall be constructed to a specification which can be shown to
meet the requirements for the relevant FRP when tested in accordance with section 3 of
BS 476: 1951.
Section 164 (1)
All fire doors shall be fitted with automatic door closed of the hydraulically spring operated
type in the case of swing doors and of wire rope and weigh type in the case of sliding door.
Fire Resistant Doors are used to separate compartments in building to stop the spreading of
fire. It suppresses the fire by restricting the flow of oxygen and spread of flames. Single Leaf
door of 900mm x 2100mm are used at the computer lab, multipurpose hall, reading area and
saloon.
Figure 2: Single leaf fire-rated
door.
Dimension: 900mm x 2100mm
Figure 3: Fire-rated
door dimension

ii) FIRE STAIRCASE
Section 165: Exits to be accessible at all times
(1) Except as permitted by-law 167 not less than TWO separate exits shall be provided
form each storey together with such additional exits as may be necessary.
Section 168: Staircases
(1) Except as provided for in by-laws 194 every upper floor shall have means of egress
via at least two separate staircases.
(2) Staircases shall be of such width that in the event of any one staircase not being
available for escape
purpose the remaining staircases shall accommodate the highest occupancy load of
any one floor discharging into it calculated in accordance with provisions in the
Seventh Schedule to these Bylaws.
(3) The required width of staircase shall be the clear width between walls but handrails
may be permitted to encroach on this width to a maximum of 75 millimeters.
(4) The required width of a staircase shall be maintained throughout its length including at
landings.
(5) Doors giving access to staircases shall be so positioned that their swing shall at no
point encroach on the required width of the staircase or landing.
Fire staircases are vertical escape component of evacuation route, easily accessible from the
inside and outside of the building. It is designed for emergency escapes while also allowing
Figure 4: Fire Staircase width is
maintained throughout its length
including at landings.

firemen to enter the building in an even of fire. There are 2 fire staircases in the building, one
nearer to the front and another at the back. They allow the users to choose the safest and
nearest escape route during the case of emergency. The fire staircases are made up of
reinforced concrete as it is fire resistant.

iii) EMERGENCY EXIT SIGNAGE
According to UBBL 1984
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 exit is not immediately
apparent.
(3) Every exit sign shall have the word “KELUAR” in plainly legible letters not less than
150 millimeters high with the principal strokes of the letters not less than 18
millimeters wide. The lettering shall be In red against a black background.
(4) All exits 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.
An exit sign is a device in facilities denoting the location of the emergency exit, guiding
people to the closest exit in case of fire or other emergency. Most relevant codes require exit
signs to be permanently lit. Exit signs are designed to be absolutely unmistakable and
understandable to anyone.
Figure 5: Emergency exit signage
Figure 6: Emergency exit signage height should be placed
above the door and exceeding 2.7min height from floor.
Figure 7: Dimension of the emergency exit signage

(iv) EMERGENCY LIGHT
An emergency light is a battery-backed lighting device that comes on automatically when a
building experiences a power outage. It is fitted with charged battery to illuminate along exit
access pathways leading to exits, exit stairs, aisles, corridors, ramps, and at the exit discharge
pathways that lead to a public way. The level of illumination, quality and consistency of
emergency illumination are important for the building occupants’ safety during fire escapes.
Figure 8: Emergency Light

4.1 Introduction to Air Conditioning
Air conditioning is any process of removing heat from a space by cooling the air. This process
also typically results in the lowering of the humidity of the air. The primary purpose of this
process is to create a more comfortable thermal environment for its occupants. Air
conditioning is also required for some rooms that may have large amounts of heat-sensitive
equipment, such as server rooms or laboratories.
How Air Conditioning Works?
An air conditioning works by displacing heat in a space into the outdoor environment.
Principally it is accomplished by means of:
i) Transferring heat into a medium
ii) Transporting medium into the outdoor environment
iii) Transferring heat from medium into outdoor environment
Typically, this is done via means of having a fan to
suck into air from a space through a series of pipes
where the heat energy is transferred into the pipes
where there is the medium fluid called refrigerant.
The refrigerant is at this point in a gaseous state, but
when pumped outside it is compressed and
condensed into a liquid state. While it is done so, an
outside fan sucks outdoor air through a separate
series of pipes where the energy from the refrigerant
is transferred to the air, cooling it. The now cooled refrigerant is then pumped back into the
indoors where the cycle continues. This process is known as the refrigeration cycle.
4 Air Conditioning System
Figure 1: Refrigeration cycle

Types of Air Conditioning
Air conditioning can be split or packaged system. A split system would have at least two
separated physical units, the compressor outdoors and the air conditioning unit indoors. A
packaged system would have the entire air conditioning unit (compressor, condenser, AHU,
etc) in one single system.
For use in commercial units (or buildings with many rooms), air conditioning is typically of a
split system, because the split system has the advantage of being able to be centralized, and
reduce the overall amount of actual air conditioning units (compressor units).
A centralized split system typically composes of a large compressor unit, an air handling unit
(AHU) which then pumps cold air via ducts into the indoor spaces. While traditionally an
AHU requires a separate room to house the large complicated machinery, newer models today
are “packaged” in the sense that the AHU and compressor/condenser unit are in one single
physical box, thus not needing any separate rooms.

4.2 Literature Review : Centralized Air Conditioning
Introduction to Centralized Air Conditioning
 The typical central air conditioning system is a split system, with an outdoor air
conditioning, or "compressor-bearing unit" and an indoor coil, which is usually installed
on top of the furnace in the home.
 Using electricity as its power source, the compressor pumps refrigerant through the system
to gather heat and moisture from indoors and remove it from the home.
 Heat and moisture are removed from the home when warm air from inside the home is
blown over the cooled indoor coil. The heat in the air transfers to the coil, thereby
"cooling" the air.
 The heat that has transferred to the coil is then "pumped" to the exterior of the home, while
the cooled air is pumped back inside, helping to maintain a comfortable indoor
temperature.
 Central air conditioning can also be provided through a package unit or a heat pump.
Centralized Air Conditioning System Benefits
 Indoor comfort during warm weather – Central air conditioning helps keep your home
cool and reduces humidity levels.
 Cleaner air – As the central air conditioning system draws air out of various rooms in the
house through return air ducts, the air is pulled through an air filter, which removes
airborne particles such as dust and lint. Sophisticated filters may remove microscopic
pollutants, as well. The filtered air is then routed to air supply duct-work that carries it
back to rooms.
 Quieter operation – Because the compressor-bearing unit is located outside the home, the
indoor noise level from its operation is much lower than that of a free-standing air
conditioning unit.

Types of Centralized Air Conditioning
A central air conditioner is either a split-system unit or a packaged unit. In a split-system
central air conditioner, an outdoor metal cabinet contains the condenser and compressor, and
an indoor cabinet contains the evaporator.
In a packaged central air conditioner, the evaporator, condenser, and compressor are all
located in one cabinet, which usually is placed on a roof or on a concrete slab next to the
house's foundation. This type of air conditioner also is used in small commercial buildings.
Air supply and return ducts come from indoors through the home's exterior wall or roof to
connect with the packaged air conditioner, which is usually located outdoors.
Air Conditioning System Components
The air conditioning part of your "split system" includes a compressor, a fan, condenser coil,
evaporator coil and a refrigerant. The system extracts heat from indoor air and transfers it
outside, leaving the cooled indoor air to be recirculated. Air conditioning and cooling
efficiency is measured using a Seasonal Energy Efficiency Ratio (SEER). A higher SEER
signifies higher energy efficiency.
The basic components of an air conditioning system:
 >A Condensing Unit (the outdoor section)
 >A matching indoor Air Handler or Gas Furnace with coil
 >Ductwork to transfer the cooled air throughout the building.


Part III – Space, Light and Ventilation
41. Mechanical Ventilation and Air-Conditioning
1. Windows and openings allowing uninterrupted air passage is not necessary if the rooms are
equipped with mechanical ventilation or air-conditioning.
2. In case air-conditioning failure there should be alternative ways to introduce 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 no necessary if the toilets are
.
The UBBL does not state specifically what air conditioning systems are required and for
spaces, thus the choice and installation of the air conditioning is dependent on the expertise of
the design team.

4.4 Proposed Air Conditioning System:
ZONED PACKAGED AIR COOLED CENTRALIZED DUCTED AIR
CONDITIONING
4.4.1 Introduction and Recommendation
This system is widely used in many medium sized commercial and residential buildings to
provide an efficient method of distributing cooling air to a large number of spaces. It is a
simple, low maintenance system that does not require any additional M/E or AHU rooms to
be provided for, also has the capacity to either recycle or to introduce outside air into the
building.
4.4.2 Terminology
Zoned – Zoned air conditioning systems are used when there are two distinct areas where
cooling needs may be different. Zoned systems can also be used when there is the energy
consumption is too big for a single unit to handle. Zoned systems have the advantage of a
failsafe, and thus if a single unit fails, another unit can still be used.
Packaged – Refers to the integration of the compressor unit and the AHU unit into a single
unit which then sits on the foundation or on the roof of the building. This does not require an
additional AHU room on each floor, minimizing its footprint and easing its construction.
Air cooled – Refers to the condenser unit being air cooled instead of water cooled. This
allows for far simpler installation, as no additional water reservoir and cooling tower is
needed to provide the cooling fluid.
Centralized – Refers to the only cooling unit in the entire system – the packaged condenser
and AHU unit. All of the cooling and heating elements are located in one centralized system.
Ducted – Refers to the necessity of installing air ducts to provide cooling air throughout the
entire building while also extracting hot air from any given space. These ducts will then

channel hot air to the centralized condenser/AHU unit to be cooled before be resent back into
the spaces.
4.4.3 Equipments and Components
Figure 2: Packaged rooftop
unit
Figure 3: Sheet aluminium
ducting
Figure 4: Ceiling mounted
register
PACKAGED AIR COOLED COMPRESSOR, CONDENSER
AND AHU UNIT
This unit includes all the necessary cooling equipment needed to
channel hot air out of a space, cool it, and then provide enough
pressure to be channeled back into the building through ducting. It
is an all in one unit (compressor, condenser and AHU) and thus
does not require any AHU rooms. It is air cooled, and thus does not
require an additional water supply and cooling tower
DUCTING
Made of non-porous material, typically metal (aluminium),
ducting channels the hot interior air to the packaged unit and
channels the cooled air back down into the spaces. Ducting
can be in many forms, and the diameter of the ducting is
dependent on the CFM value of a space.
REGISTERS/DIFFUSERS/GRILLE
These openings are serve as the aperture in which the cooled
air from the ducts enters a room. While the terminology is
specific (a register is a diffuser that has openable grilles),
typically it is called a register. A register has controls that
allow the amount of cooled air entering a space, allowing
temperature control
INTAKE SUPPLY GRILLE
Intake grilles are openings to lower pressure environments
allowing hot air to be channeled through into the intake ducts
to be transferred to the packaged cooling unit.
Figure 5: Intake supply
grille

4.4.4 Air Conditioning Sizing
As it is essential that each room be adequately cooled, the air conditioning system has to be
correctly sized, to provide a cooling solution that is both economical yet powerful. To do this,
a few units are used to accurate assess an air conditioning sytem.
BTU – British thermal unit, equivalent to 1055 joules. It is the amount of work needed to
raise the temperature of 1 pound of water by 1 degree F. Used in calculating amount of
cooling work needed.
Or Ton of cooling – Used by the US, equivalent to 12,000 BTU/h (3.52KW). It is the amount
needed to freeze 907 kg of water into ice in 24 hours. Not used here in Malaysia.
SEER rating – Used to assess the efficiency of an air conditioning unit, the higher the value,
the more efficient the air conditioning unit is. Typical SEER ratings vary from 10 – 33.
CFM – Cubic feet/minute. It is the volume of air at sea level that is being displaced per
minute. This is especially important in selecting the correct size of the ducting system.
(i) Selecting an appropriate air conditioning unit
Rule of thumb method: [(Gross square feet of building x 25)/12000] – 0.5 = amount of
Ton of cooling. Some air conditioning manufacturers do list their products in Tons of
cooling. To convert to BTU/h, multiply by 12,000.
For this building, the calculation is as follows:
Gross SF of building = 4305.
Amount of Ton of cooling: 8.5
BTU/h amount = 101,625.
The DAIKIN UATQ120C 10 kilowatt packaged air conditioning unit has a BTU/h of
124,500, and thus would be suitable for this building. Note, packaged air conditioning units
have a typically lower SEER rating than split units, at around 14.

(ii) Selecting an appropriate ducting system
Ducting can be categorized into two: flexible and rigid. Rigid ducting is mainly
composed of sheet aluminium that is not flexible, and is typically of a large size requiring
large amounts of space. Flexible ducting can be found in smaller diameters, and is made
of metal foil lined with non-porous material. This system does not require much space,
and thus is most suitable for this building.
Figure 6: Table for duct diameter according to CFM
Rule of thumb method: 1 square foot of floor area is roughly equivalent to 1 cubic
feet/minute of air flow. Thus, it is a simple method of choosing
the diameter of the duct depending on the area of the room. Not
all ducts must be of the same diameter, as it depends on the area
of each individual room.
Ducting Diameter Schedule
Room Area m2/sqf Duct diameter
Cafe 21.7m2/233.5sqf 9”
Kitchen 10.4m2/112sqf 7”
Dental 12m2/130sqf 7”
Sickbay 12m2/130sqf 7”
Lobby 35.7m2/384sqf 12”
Office 13m2/140sqf 8”
Computer Lab 44.4m2/473sqf 12”
Reading Area 37m2/398sqf 12”
Caretaker accommodation 37m2/398sqf 12”
Saloon 60m2/645sqf 14”
Massage 14.4m2/155sqf 7”
Multipurpose Hall 94m2/1011sqf 16”

5.1 Introduction to Mechanical Ventilation
Introduction
Ventilation is necessary in buildings to remove ‘stale’ air and replace it with ‘fresh’ air.
Generally, it helps in moderating internal temperatures, creating air movement which
improves the comfort of occupants. Very broadly, ventilation in buildings can be classified as
‘natural’ or ‘mechanical’. Mechanical (or ‘forced’) ventilation tends to be driven by fans.
Whereas, natural ventilation is driven by ‘natural’ pressure differences from one part of the
building to another. Natural ventilation can be wind-driven or buoyancy-driven such as Stack
effect and Cross Ventilation.
The design of mechanical ventilation systems is generally a specialist task, undertaken by a
building services engineer. Whilst there are standards and rules of thumb that can be used to
determine air flow rates for straight-forward situations, when mechanical ventilation is
combined with heating, cooling, humidity control and the interaction with natural ventilation,
thermal mass and solar gain, the situation can quickly become very complicated. This, along
with additional complications, such as the noise generated by fans, and the impact of
ductwork on acoustic separation means it is vital building services are considered at the outset
of the building design process, and not seen as an add-on.
5 Mechanical Ventilation System

In commercial developments, mechanical ventilation is typically driven by air handling units
(AHU) connected to ductwork within the building that supplies air to and extracts air from the
interior. Typically they comprise an insulated box that forms the housing for; filter racks or
chambers, a fan (or blower), and sometimes heating elements, cooling elements, sound
attenuators and dampers. In some situations, such as in swimming pools, air handling units
might include dehumidification. See Air handling units for more information.
Where mechanical ventilation includes heating, cooling and humidity control, this can be
referred to as Heating Ventilation and Air Conditioning (HVAC).
Extracting internal air and replacing it with outside air can increase the need for heating and
cooling. This can be reduced by re-circulating a proportion of internal air with the fresh
outside air, or by heat recovery ventilation (HRV) that recovers heat from extract air to pre-
heat incoming fresh air using counter-flow heat exchangers.
Mechanical ventilation may be controlled by a building management system (BMS) to
maximise occupant comfort and minimise energy consumption. Regular inspection and
maintenance is necessary to ensure that systems are operating optimally and that occupants
understand how systems are operated.

TYPES OF BASIC MECHANICAL WHOLE-HOUSE VENTILATION SYSTEMS:
(i) Exhaust
Exhaust ventilation systems work by depressurizing your home. The system exhausts air from
the house while make-up air infiltrates through leaks in the building shell and through
intentional, passive vents.
Exhaust ventilation systems are most appropriate for cold climates. In climates with warm
humid summers, depressurization can draw moist air into building wall cavities, where it may
condense and cause moisture damage.
(ii) Balanced
Balanced ventilation systems, if properly designed and installed, neither pressurize nor
depressurize your home. Rather, they introduce and exhaust approximately equal quantities of
fresh outside air and polluted inside air.

(iii) Energy Recovery
Energy recovery ventilation systems provide a controlled way of ventilating a home while
minimizing energy loss. They reduce the costs of heating ventilated air in the winter by
transferring heat from the warm inside exhaust air to the fresh (but cold) outside supply air. In
the summer, the inside air cools the warmer supply air to reduce cooling costs.
There are two types of energy-recovery systems: heat-recovery ventilators (HRV) and energy-
recovery (or enthalpy-recovery) ventilators (ERV). Both types include a heat exchanger, one
or more fans to push air through the machine, and controls. There are some small wall- or
window-mounted models, but the majority are central, whole-house ventilation systems with
their own duct system or shared ductwork.
(iv) Supply (Applied on this project)
Supply ventilation systems use a fan to pressurize your home, forcing outside air into the
building while air leaks out of the building through holes in the shell, bath, and range fan
ducts, and intentional vents (if any exist).

5.2 Literature Review : Supply Ventilation System
Nowadays, because of central heating and cooling, as well as the desire for privacy, people
tend to make little use of windows for ventilation, so infiltration has become the principal
mode of natural ventilation in homes. Unfortunately, a home’s natural infiltration rate is
unpredictable and uncontrollable because it depends on the home’s air tightness, outdoor
temperatures, wind, and other factors. During mild weather, some homes may lack sufficient
ventilation for pollutant removal. Tightly built homes may have insufficient ventilation at
most times. This axiom implies that houses should be tightly sealed to reduce infiltration, and
a mechanical ventilation system installed to provide fresh air and remove pollutants when and
where needed, in a controlled manner(i.e., in amounts needed) that does not negatively impact
indoor air quality, building components, or heating and cooling bills. Therefore, mechanical
ventilation still comes into play. In Malaysian context, Supply Ventilation System works
extremely well due to our hot and humid climate. The Elderly Centre is located in a relatively
flat topology, therefore passive ventilation is not as effective. Fresh air is retrieved from a
higher point and pressurises the inner of the house, pushing the stale air out, creating air
movement thus, and increasing the users’ comfort.
How Supply Ventilation System Works?
Like exhaust ventilation systems, supply ventilation systems are relatively simple and
inexpensive to install. A typical supply ventilation system has a fan and duct system that
introduces fresh air into usually one -- but preferably several -- rooms that residents occupy
most (e.g., bedrooms, living room). This system may include adjustable window or wall vents
in other rooms.
Supply ventilation systems allow better control of the air that enters the house than exhaust
ventilation systems do. By pressurizing the house, supply ventilation systems minimize
outdoor pollutants in the living space and prevent back drafting of combustion gases from
fireplaces and appliances. Supply ventilation also allows outdoor air introduced into the house
to be filtered to remove pollen and dust or dehumidified to provide humidity control.
Supply ventilation systems work best in hot or mixed climates. Because they pressurize
the house, these systems have the potential to cause moisture problems in cold climates. In
winter, the supply ventilation system causes warm interior air to leak through random

openings in the exterior wall and ceiling. If the interior air is humid enough, moisture may
condense in the attic or cold outer parts of the exterior wall, resulting in mould, mildew, and
decay.
Like exhaust ventilation systems, supply ventilation systems do not temper or remove
moisture from the make-up air before it enters the house. Thus, they may contribute to higher
heating and cooling costs compared with energy recovery ventilation systems. Because air is
introduced into the house at discrete locations, outdoor air may need to be mixed with indoor
air before delivery to avoid cold air drafts in the winter. An in-line duct heater is another
option, but increases operating costs.

Part III – Space, Light and Ventilation
41. Mechanical Ventilation and Air-Conditioning
1. Windows and openings allowing uninterrupted air passage is not necessary if the rooms are
2. In case air-conditioning failure there should be alternative ways to introduce 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 no necessary if the toilets are

5.4 Components involved in Supply Ventilation System
Fan
-To remove hot and polluted air.
-To bring in outdoor air to comfort the people or to cool the building.
-To circulate indoor air
Located in the attic, to hide the ductworks and avoid noise pollution.
Central Supply Fan
Figure 7
Filter
-To sift the external air before releasing air into the room
-To trap and prevent dust, smoke, bacteria, etc. from entering the room
-Different filter for different applications
Installed at the inlet grille to avoid dirty substances from entering the compound.
Figure 8

Ductwork
-To channel outside air towards the room or the air from the room towards the outside
-Usually in round or rectangular section
Rectangular Ducts
Rounded Ducts
Mechanical Damper
-In occurrence of fire, to avoid the fire from spreading from one room to another.
-Usually placed at compartment walls.

Grille & Diffuser
-Located at the edge of the ductwork where the air is released into the room.

6.1 Introduction to Mechanical Transportation System
Mechanical Transportation refers to transportation system that is used to move or transport
goods and people vertically or horizontally, such as elevator, escalator and travellators. In this
particular assignment, as the project context only consist of elevator, the review will be
elaborating on mechanism of elevator.
An elevator is defined as a permanent lifting equipment serving two or more landing levels,
including a car for transportation of passengers and/or other loads, running at least partially
between rigid guide rails, either vertical or inclined to the vertical by less than 15 degrees.
Elevator is an integral part of all multi-storey buildings, as it provide important access for
goods and people throughout the floors. Especially for the disabled and elderly, where stairs
and ramps are deemed impractical, elevators are often a legal requirement in new multi-storey
buildings according to wheelchair access laws.
Elevators may be classified according to the following technical parameters:
1. Hoist Mechanism
- Elevators can be classified according to hoist mechanism to 4 main types : 
i) Hydraulic Elevators
ii) Traction Elevators
iii) Climbing Elevators
iv) Pneumatic Elevators
6 Mechanical Transportation System

2. Building Height
- i) Low-Rise Building (1-3 Stories)
:Typically uses hydraulic elevators because of lower initial cost.  
ii) Mid-Rise Building (4-11 Stories)
:Typically uses Geared Traction Elevator.
iii) High-Rise Building (12 Stories and above)
:Typically uses Gear-less Traction Elevator.
3. Building Type & Uses
- i) Hospital Elevators
ii) Residential/Domestic Elevators
iii) Agricultural Elevators
iv) Industrial Elevators
v) Commercial Elevators
vi) Parking Buildings Elevators

6.2 Literature Review : Hydraulic Elevator
Hydraulic elevators are used primarily in
low and mid-rise installations, where
moderate car speed ( up to 150 ft. per
minute ) is acceptable. A car is connected
to the top of a piston that moves up and
down in cylinder from a reservoir, raising
the piston. The car is lowered when the
hydraulic fluid returns to the reservoir. The
up and down motions of the elevator car are
controlled by the hydraulic valve.
The main space planning elements of a
hydraulic elevator are the machine room,
usually located at the base, at the hoist way,
which serves as a fire-protected, ventilated
passageway for the elevator car. Adequate
structure must be provided at the base of
the hoist-way to bear the load of the
elevator car and its supporting piston or
cylinder.
There are three configuration of hydraulic elevators : holed, hole-less, and roped hydraulic.
The cylinder in a holed hydraulic elevator is centred below the car and bored into the earth.
The cylinder depth will be approximately equal to the travel distance plus the pit both sides of
the car and do not penetrate below the elevator pit. Hole-less hydraulic elevators have
substantially less travel than holed types. With roped hydraulic elevators, a plunger moves the
Fig 3. Conventional Hydraulic Elevator

cables or ropes, which then moves the elevator car. All three configurations can be used in
commercial applications, but holed and hopeless are the most common types.

6.3 Mechanical Transportation Laws
124. For all non-residential buildings exceeding 4 storeys above or below the main access
level at least one lift shall be provided.
151. Ventilation to Lift Shafts
Where openings to lift shafts are not connected to protected lobbies, such lift shafts shall be
provided with vents of not less than 0.09 square metre per lift located at the top of the shafts.
Where the vent does not discharge directly to the open air the lift shafts shall be vented to the
exterior through a duct of the required FRP as for the lift shafts.
152. Openings in Lift Shafts
(1) Every opening in a lift shaft or lift 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
buildings as may be approved by the D.G.F.S.
(2) Landing doors shall have a FRP of not less than half the FRP of the hoistway structure
with a minimum FRP of half hour.
(3) No glass shall be used for in landing doors except for vision in which case any vision
panel shall or be glazed with wired safety glass, and shall not be more than 0.0161 square
metre and the total area of one of of more vision panels in any landing door shall be not more
than 0.0156 square metre.
(4)Each clear panel opening shall reject a sphere 150 milimetres in diameter.
(5)Provision shall be made for the opening of all landing doors by means of an emergency
key irrespective of the position of the lift car.

153. Smoke Detectors for Lift Lobbies
(1) All lift lobbies shall be provided with smoke detectors.
(2) Lift not opening into a smoke lobby shall not use door reopening devices controlled by
light beam or photo-detectors unless incorporated with a force close feature which after thirty
seconds of any interruption of the beam causes the door to close within a preset time.
154. Emergency Mode of Operation in the Event of Main Power Failure
(1) On failure of mains power all 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.
(2) After all lifts are parked the lifts on emergency power shall resume normal operation:
Provided that where sufficient emergency power is available for operation of all lifts, this
mode of Operation need not apply.
155. Fire mode of Operation
(1) The fire mode of operation shall be initiated by a signal from the fire alarm panel which
may be activated automatically by one of the alarm devices in the building or manually.
(2) If main 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.
(3) The fire lifts shall then be available for use by the fire bridgade on operation of the
fireman’s switch.
(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.
(5) In the event of main power failure, all lifts shall return in sequence directly to the
designated floor and operate under emergency power as described under paragraphs (2) to (4).

Due to the circumstances that the project brief calls for design for the elderly, the
following codes are also reviewed and referenced:
MS1184:2002 - Code Of Practice On Access for Disabled Persons to Public Buildings
10. Lifts
10.1 Every lift forming part of vertical access for the disabled persons should have an
unobstructed depthin front of the lift doors of not less than 1800mm.
10.2 It should maintain a floor level accuracy within a tolerance of 10mm throughout the
range of rated load.
10.3 The handrail in the lift car should not be less than 600mm long at 1000mm above the
finished floor level and should be fixed adjacent to the control panel.
10.4 At least one lift car, adjacent to a public entrance that is accessible for disabled persons,
should be designed as a lift for wheelchair users, complying to all the sub-clauses of this
clause, and should have space for a wheelchair to be turned through 180’ inside the lift in
accordance with figure 8.
Figure 8. Lift Car Requirement

10.5 The lift door installation should provide the following:
A) Should provide a clear opening of not less than 800mm in accordance with figure 8.
B) Sensing devices should be provided to ensure that lift car and landing doors will not close
while the opening is obstructed, subject to the nudging provisions which operate if the door is
held open for more than 20s; and
C) If sensing devices as in b) above are not provided, the dwell time of an automatically
closing door should not be less than 5s and the closing speed should not exceed 0.25m/s.
10.6 Lift controls should comply with the following:
A) Controls should be clearly indicated and easily operated in accordance with clause 27.
B) Call buttons should either project from or be flush with the face of the car-operating panel.
The width or diameter of the buttons should not be less than 20mm.
C) Floor buttons, alarm buttons or emergency telephone and door control buttons in lift cars
and lobbies should not be higher than 1400mm above finished floor level. The hearing
impaired can use an alarm button and not the emergency telephone. An alarm button should
always be provided, and preferably of a design which ights up and produce sound when
pressed to reassure those trapped inside.
D) All buttons should be so designed that the sight impaired can identify them by touch.
Button not already so designed are best modified by fixing, embossed or braille

6.4 Proposed Mechanical Transportation System:
Hole-less Machine-less Hydraulic Elevator
Due to the consideration of the project, which is a low-rise 3 storeys public building in
serving of elderly people, we have chosen Machine-Roomless Holeless Hydraulic Elevator
with extra width that accordes to MS1184, to accommodate Machine-Roomless Holeless
Hydraulic Elevators are supported by pistons at the sides of the elevator that pushes the
elevator up, and doesn’t require an additional machine room, which eliminate the needs for
extra space, thus saving unnecessary space for the center.

Compared to conventional elevator, machine-less holeless hydraulic elevator eliminates the
need of any extra machine room as shown in the left picture, saving space and allowing it to
be compact as shown in the right picture.
MECHANISM OF HYDRAULIC ELEVATOR:
Oil Hydraulic Lift Application:
The pump forces fluid from the tank into a pipe leading to the cylinder. When the valve is
opened, the pressurized fluid will take the path of least resistance and return to the fluid
reservoir. But when the valve is closed, the pressurized fluid has nowhere to go except into
the cylinder. As the fluid collects in the cylinder, it pushes the piston up, lifting the elevator
car.

When the car approaches the correct floor, the control system sends a signal to the electric
motor to gradually shut 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 cannot escape (it can't flow backward
through the pump, and the valve is still closed). The piston rests on the fluid, and the car stays
where it is.
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 can 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. To stop the car at a lower floor, the control system closes the valve again.
Components of Direct Acting Mechanism:

1.A Plunger/Piston/Jack
The cylinder shall be constructed of steel pipe of a sufficient thickness and suitable safety
margin. The top of the cylinder shall be equipped with a cylinder head with an internal guide
ring and self-adjusting packing.
The plunger/piston/jack shall be constructed of a steel shaft of a proper diameter machined
true and smooth. The plunger/piston/jack shall be provided with a stop electrically welded to
the bottom to prevent the plunger from leaving the cylinder.
1.B Hydraulic Power Unit
The power unit shall be generously rated and shall operate with minimum noise and vibration.
The unit shall be mounted on vibration insulators above the machine room floor. A silencer
unit shall be fitted in the hydraulic system to minimize the transmission of pulsations from the
pump to the car and the elimination of airborne noise.
The hydraulic power unit consists of the following components:
A. The Tank.
The tank shall have sufficient capacity to provide an adequate reserve to prevent the
entrance of air or other gas into the system. A sight glass tube shall be provided for
checking the oil level and the minimum level mark shall be clearly indicated. An oil
level monitoring device shall be provided, and if operated, shall maintain a visual and
audible signal in the control panel until the fault is rectified.
So, the main function of the tank is holding the liquid used in the system, This liquid is
usually oil based because:
- Non compressible.
- Self lubricating.

B. Motor/Pump.
The main function of the pump used in hydraulic elevator is constantly pushing Liquid
into the cylinder to lift the elevator, the pump is Submersible type with Variable Speed
Valve Leveling.
The pump and pump motor shall be mounted on one robust bedplate or within the power
unit assembly if it is suitably rigid. The motor pump and bearing(s) shall be so mounted and
assembled that proper alignment of these parts is maintained under all normal operating
conditions.
An oil filter shall be fitted on the pump inlet. A stopcock shall be provided to enable the
filter to be cleaned or changed without significant loss of oil. The pump motor shall be of the
single speed squirrel cage or slip ring type and it shall run with minimum noise and vibration.
C. Valve.
The power unit control valve shall be a variable speed proportional valve type that
includes all hydraulic control valving inherently. A stopcock shall be provided between
the control valves and the cylinder(s), and also between the reservoir tank and the pump if
the pump is mounted outside the tank.

In conclusion, we have understand and learn about the workability and functions of each and
every system in depth according to the by laws after completing this assignment. For example,
through fire protection system, it will help to ensure that the building have the necessary
requirements to help guide the inhabitants escape out from the building. In mechanical
ventilation, optimal ventilation system that suits the local climatic condition will help the
building to achive optimal thermal comfort for the inhabitants. Through the study of mechanical
transportation, we are able to propose and integrate suitable tranposrtation mechanism and
methods that can aid inhabitants to move from floor to floor, especially for disabled persons.
Besides that, we also understand how each building services functions complements each other
and helps to serve the building better and safer. Throughout this exercise, we are able to propose
and integrate various building services into a building as well as prepare drawings for each
proposed system.
7Summary

8 References
1. Central Air Conditioning. (n.d.). Retrieved November 17, 2016, from
http://www.energy.gov/energysaver/central-air-conditioning
2. Greeno, R. 2000. Building Services Equipment. 5th
Edition, Longman
3. Hall, Frederick E. 1997. Building Services and Equipment. Volume 2. 2nd
Edition
4. Malaysian Standard 1184 Code of practice on access for disabled person to Public
Buildings
5. Uniform Building By-Laws 1984
6. Stein, Benjamin & Reynolds, John S. 2000. Mechanical and Electrical equipment
for Buildings. New York, John Wiley
7. Central Air Conditioning. (n.d.). Retrieved November 24, 2016, from
http://energy.gov/energysaver/central-air-conditioning
8. Central Air Conditioning Buying Guide. (n.d.). Retrieved November 24, 2016, from
http://www.consumerreports.org/cro/central-air-conditioning/buying-guide.html
9. Heating & Cooling 101. (n.d.). Retrieved November 24, 2016, from
http://www.goodmanmfg.com/resources/heating-cooling-101/how-central-ac-
systems-work
10. Learn about your Central Air Conditioning. (n.d.). Retrieved November 24, 2016,
from
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