Lift 1
Lift 1
Lift 1
ESCALATORS
ELEVATORS
An elevator is a type of vertical transport equipment.
Elevators are generally powered by electric motors that either drive
traction cables or counterweight systems like a hoist, or pump
hydraulic fluid to raise a cylindrical piston like a jack.
Because of wheelchair access laws, elevators are often a legal
requirement in new multistory buildings, especially where
wheelchair ramps would be impractical.
A modern day lift consists of a cab mounted on a platform within an
enclosed space called a shaft or sometimes a “ hoistway “.
Hydraulic lifts use the principles of hydraulics to pressurize an
above ground or in-ground piston to raise and lower the car.
Roped hydraulics use a combination of both ropes and hydraulic
power to raise and lower cars.
Hydraulic lifts are cheaper, but installing cylinders greater than a
certain length becomes impractical for very high lift hoistways.
Hydraulic lifts are usually slower than traction lifts.
Machine room-less (MRL) elevators
Machine room-less elevators are designed so that most of the
components fit within the shaft containing the elevator car; and a
small cabinet houses the elevator controller. Other than the
machinery being in the hoistway, the equipment is similar to a
normal traction elevator.
Benefits
• creates more usable space
use less energy (70-80% less than hydraulic elevators)
uses no oil
slightly lower cost than other elevators
can operate at faster speeds than hydraulics but not normal traction
Units.
Types of hoist mechanisms
There are at least four means of moving an elevator:
1. Traction elevators
• Geared and gearless traction elevators
Geared traction machines are driven by AC or DC electric motors.
Geared machines use gears to control mechanical movement of
elevator cars by "rolling" steel hoist ropes over a drive sheave
which is attached to a gearbox driven by a high speed motor.
These machines are generally the best option for basement or
overhead traction use for speeds up to 500 ft/min (2.5 m/s).
• Gearless traction machines are low speed, high torque electric
motors powered either by AC or DC. In this case, the drive sheave
is directly attached to the end of the motor. Gearless traction
elevators can reach speeds of up to 2,000 ft/min (10 m/s), or even
higher. A brake is mounted between the motor and drive sheave to
hold the elevator stationary at a floor.
GEARLESS
TRACTION
ELEVATORS
GEARED
TRACTION
ELEVATORS
• Elevators with more than 100 ft (30 m) of travel
have a system called compensation. This is a
separate set of cables or a chain attached to the
bottom of the counterweight and the bottom of the
elevator cab. This makes it easier to control the
elevator, as it compensates for the differing weight
of cable between the hoist and the cab
2. Hydraulic elevators
Conventional hydraulic elevators. They use an
underground cylinder, are quite common for low
level buildings with 2–5 floors (sometimes but
seldom up to 6–8 floors), and have speeds of up
to 200 feet/minute (1 meter/second).
Holeless hydraulic elevators were developed in
the 1970s, and use a pair of above ground
cylinders, which makes it practical for
environmentally or cost sensitive buildings with 2,
3, or 4 floors.
Roped hydraulic elevators use both above ground
cylinders and a rope system, allowing the
elevator to travel further than the piston has to
move.
The low mechanical complexity of hydraulic elevators in comparison to
traction elevators makes them ideal for low rise, low traffic installations.
They are less energy efficient as the pump works against gravity to push
the car and its passengers upwards; this energy is lost when the car
descends on its own weight. The high current draw of the pump when
starting up also places higher demands on a building’s electrical system.
3. Traction-Hydraulic Elevators
The traction-hydraulic elevator has overhead traction cables and
counterweight, but is driven by hydraulic power instead of an overhead
traction motor. The weight of the car and its passengers, plus an
advantageous roping ratio, reduces the demand from the pump to raise
the counterweight, thereby reducing the size of the required machinery.
4. Climbing elevator
A climbing elevator is a self-ascending elevator with its own propulsion.
The propulsion can be done by an electric or a combustion engine.
Climbing elevators are used in guyed masts or towers, in order to make
easy access to parts of these constructions, such as flight safety lamps
for maintenance.
Elevator air conditioning
Concept
Elevator air conditioning is fast becoming a popular concept
around the world. The primary reason for installing an elevator air
conditioner is the comfort that it provides while traveling in the
elevator. It stabilizes the condition of the air inside the lift car.
Health
One of the benefits of installing an elevator air conditioner is the
clean air it provides. Air was typically drawn from the elevator shaft
or hoistway into the car using a motorized fan. This air could
contain dust mites, germs and bacteria. With an elevator air
conditioner, the air is much cleaner because it is recirculated within
the car itself and is usually filtered to remove contaminants. A
poorly maintained air-conditioning system may promote the growth
and spread of microorganisms, but as long as the air conditioner is
kept clean, these health hazards can be avoided.
Drawbacks
Heat generated from the cooling process is dissipated
into the hoistway. The elevator cab (or car) is not air-
tight, and some of this heat will reenter the car and
reduce the overall cooling effect, which may be less
than ideal.
Energy
The air from the lobby constantly leaks into the elevator
shaft due to elevator movements as well as elevator
shaft ventilation requirements. Using this conditioned
air in the elevator does not increase energy costs.
However, by using an independent elevator air
conditioner to achieve better temperature control
inside the car, more energy will be used.
Condensation
Air conditioning poses a problem to elevators because
of the condensation that occurs. The condensed water
produced has to be disposed of; otherwise, it would
create flooding in the elevator car and hoistway.
The following are suggested inside dimensions and rated capacities:
• Office buildings: 6 feet 8 inches wide by 5 feet 5 inches deep; 3,500 pounds.
• Apartment buildings: 6 feet 8 inches wide by 4 feet 3 inches deep; 2,500
pounds
• Hotels/motels: 6 feet 8 inches wide by 5 feet 5 inches deep; 3,500 pounds.
• Service elevators: 5 feet 4 inches wide by 8 feet 5 inches deep; 4,500 pounds.
• Hospital passenger elevators: 6 feet 8 inches wide by 5 feet 5 inches deep;
3,500 pounds.
• Hospital vehicle elevators: 5 feet 9 inches wide by 10 feet deep; 6,000
pounds.
Office buildings:
1. One elevator is required for every 45,000 net usable square feet. The ratio of the
number of floors to the
number of elevators should be two to one or two and a half to one, depending on
the occupancy of the building.
The more dense the population, the more elevators needed.
2. The number of elevators in a single group should not exceed eight and no single
group should serve more
than 16 levels.
3. In buildings of four to eight floors, a separate service elevator should be
considered. Over nine floors, a
service elevator is virtually required.
Hotels/motels:
1. Provide one elevator for every 75 rooms with a minimum of one elevator up to
three floors. Do not exceed
150 feet from farthest room to elevator.
2. When room service is provided, allow for one separate service elevator for
every two passenger elevators.
3. Special-functions, meeting rooms, or lobby areas above entry level can
increase the number of elevators.
Apartment / Condominium/Dormitory
1. One elevator for every 90 units with a maximum distance of 150 feet from
elevators to the most distant unit.
2. Urban locations or high-price units might require one elevator for every 60
units.
3. Make one elevator oversize (at least 3,500 pounds) to accommodate furniture.
In buildings 10 floors or more,
consider a separate service elevator.
PASSENGER ELEVATORS
Passenger elevators should be located at the circulation core of the
building and be grouped into banks when this is necessary and
desirable.
• The required umber of elevators is determined by:
Building type
Building height
Number of stops
Floor use
Passenger volume
FREIGHT ELEVATORS
A freight elevator, or goods lift, is an elevator designed to carry goods,
rather than passengers. Freight elevators are typically larger and
capable of carrying heavier loads than a passenger elevator, generally
from 2,300 to 4,500 kg. Freight elevators may have manually operated
doors, and often have rugged interior finishes to prevent damage while
loading and unloading. Although hydraulic freight elevators exist,
electric elevators are more energy efficient for the work of freight lifting.
SCEINIC ELEVATORS
Scenic elevators also called glass elevators are getting popular. They loosen rigour
of architecture and give passengers a visually stimulating ride between floors.This
type of elevators are suitable for luxurious buildings. It increases the passenger
sense of security.
If the technical components are to be hidden, the scenic elevator consist of entrance
area and a viewing area.The entrance area is surrounded by an enclosed shaft that
contains necessary elevator technology.The car is also enclosed in this area.
The car walls must be constructed with laminated glass with EN 81.Depending on
architecture , opaque sheet metal doors can be replaced with transluscent glass
doors in scenic elevators.
Dumbwaiter - Dumbwaiters are small freight elevators that are
intended to carry food rather than passengers. They often link
kitchens with rooms on other floors.
Paternoster -A special type of elevator is the paternoster, a
constantly moving chain of boxes. A similar concept, called
the manlift or humanlift, moves only a small platform, which the
rider mounts while using a handhold and was once seen in multi-
story industrial plants.
Scissor lift -The scissor lift is yet another type of lift. As most of
these lifts are self-contained, these lifts can be easily moved to
where they are needed.
Rack-and-pinion lift -The rack-and-pinion lift is another type of lift.
These lifts are powered by a motor driving a pinion gear. Because
they can be installed on a building or structure's exterior and there
is no machine room or hoistway required, they are the most used
type of lift for buildings under construction
CONSTRUCTION
ELEVATOR SHAFT – contain building components necessary for the
operation of elevator. Its dimension depends upon elevator model, door
design and type of drive. They must have ventilation and smoke
extracting openings. The cross section of these openings is generally
2.5% of the shaft floor area, with minimum cross section stipulated as
0.1m.sq.
SHAFT PIT – the bottom end of the shaft is called pit. The depth of the
pit is measured from the top edge of the finished floor at the lowest
elevator stop to the top edge of the finished floor of the pit floor. The
minimum depth of pit is determined by:
space required for construction
over run and safety space stipulated by regulations
The pit sits directly on the foundation. Shaft pits that are 1 to 2.5m deep
must be equipped with a removable access ladder. Pits with a depth
greater than 2.5m must have a secure access door to a building floor.
SHAFT HEAD – It is the
upper section of the shaft,
measured from the top edge
of the finished floor at the
uppermost stop to the
bottom edge of the shaft
ceiling.
SHAFT ACCESS – The size
of the shaft access points is
determined by the door
design, while their location is
defined by shaft symmetry.
MACHINE ROOM -
Depending upon the type of
drive machine room is
located either at the top
above the shaft or at the
bottom next to it.
ELEVATOR CARS
In addition to doors, the size of
the elevator shaft is also largely
determined by dimensions of
elevator car.
All elevator cars must be well lit,
with grid independent safety
lights which are battery
operated
Passenger and freight elevator
cars must be ventilated. Air
intake and exhaust openings
must be placed to ensure
sufficient diagonal and cross
ventilation.
ESCALATORS
An escalator is a moving staircase – a conveyer transport
device for carrying people between floors of a building. The
device consists of a motor -driven chain of individual, linked
steps that move up or down on tracks, allowing the step treads
to remain horizontal.
Escalators are used around the world to move pedestrian
traffic in places where elevators would be impractical.
Principal areas of usage include department stores, shopping
malls, airports, transit systems, hotels, arenas, stadiums and
public buildings.
The benefits of escalators are many. They have the capacity
to move large numbers of people, and they can be placed in
the same physical space as one might install a staircase. They
can be used to guide people toward main exits or special
exhibits, and they may be weatherproofed for outdoor use.
INCLINE AND TRANSPORTATION HEIGHT
Generally designed on an incline of
27.3, 30, 35 degrees.
35 degree escalator is most effective
since it requires least amount of
space. This incline is applicable to a
total transportation height of 6m
If the height is more than 6m than
incline of 27.3 should be given
ESCALATOR CAPACITY
Most escalators are designed with 1000mm wide steps which allow
passengers to move comfortably when carrying luggage and
shopping bags.
600mm and 800mm wide steps are also available and generally used
in low traffic areas
Standard transportation speed ranges between 0.5 to 0.65m/s
For a speed of 0.5m/s the theoretical capacity is:
600mm step width -4500 persons per hour
800mm step width -6750 persons per hour
1000mm step width -9000 persons/hour
Whenever possible its best to install two or more parallel sets of
escalators.
TYPES
Escalators have three typical configuration options:
• Parallel -up and down escalators "side by side or separated
by a distance", seen often in metro stations and multilevel
motion picture theaters
• Crisscross -minimizes structural space requirements by
"stacking" escalators that go in one direction, frequently used
in department stores or shopping centers
• Multiple parallel -two or more escalators together that travel
in one direction next to one or two escalators in the same bank
that travel in the other direction
Escalators are required to have moving handrails that keep
pace with the movement of the steps. The direction of
movement (up or down) can be permanently the same, or be
controlled by personnel according to the time of day, or
automatically.
COMPONENTS
Landing platforms -These two platforms house the
curved sections of the tracks, as well as the gears and
motors that drive the stairs. The top platform contains
the motor assembly and the main drive gear, while the
bottom holds the step return idler sprockets. These
sections also anchor the ends of the escalator truss. In
addition, the platforms contain a floor plate and a
comb plate. The floor plate provides a place for the
passengers to stand before they step onto the moving
stairs. This plate is flush with the finished floor and is
either hinged or removable to allow easy access to the
machinery below. The comb plate is the piece between
the stationary floor plate and the moving step. "freestanding" escalator reveals
inner components through the
Truss -The truss is a hollow metal structure that transparent truss
bridges the lower and upper landings. It is composed
of two side sections joined together with cross braces
across the bottom and just below the top. The ends of
the truss are attached to the top and bottom landing
platforms via steel or concrete supports.
Tracks -The track system is built into the truss to guide the step chain,
which continuously pulls the steps from the bottom platform and back to
the top in an endless loop. There are actually two tracks: one for the front
wheels of the steps (called the step-wheel track) and one for the back
wheels of the steps (called the trailer-wheel track). The relative positions
of these tracks cause the steps to form a staircase as they move out from
under the comb plate.
Steps -The steps themselves are solid, one piece, die-cast aluminum or
steel. Yellow demarcation lines may be added to clearly indicate their
edges. The steps are linked by a continuous metal chain that forms a
closed loop. The front and back edges of the steps are each connected
to two wheels. The rear wheels are set further apart to fit into the back
track and the front wheels have shorter axles to fit into the narrower front
track. As described above, the position of the tracks controls the
orientation of the steps