Post on 06-Feb-2018
Project Report on Development of “Kotappakonda
Aerial Ropeway Project”
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2015
KOTAPPAKONDA AERIAL
ROPEWAY PROJECT Volume II- Project Information Memorandum
Department of Tourism, Government of Andhra Pradesh
Design, Engineering, Development, Construction, Testing,
Commissioning, and Operation & Maintenance of a
Ropeway System at Kotappakonda Temple in Andhra
Pradesh under Public Private Partnership (PPP) Mode
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TABLE OF CONTENTS
TABLE OF CONTENTS ........................................................................................................................................ 2
1. INTRODUCTION ............................................................................................................................................ 3
1.1. OBJECTIVE OF THIS PROJECT REPORT ............................................................................................................. 3
1.2. EXECUTIVE SUMMARY ............................................................................................................................... 3
1.3. PROJECT DETAILS...................................................................................................................................... 4
2. PROJECT DETAILS .................................................................................................................................... 7
2.1. PROJECT BACKGROUND ............................................................................................................................. 7
2.2. LOCATION AND DEMOGRAPHIC DETAILS OF THE REGION .................................................................................. 9
2.3. PROJECT SITE ......................................................................................................................................... 11
2.4. PROJECT NEED ....................................................................................................................................... 12
2.5. STAKEHOLDER ANALYSIS ........................................................................................................................... 12
3. PROJECT DESIGN ................................................................................................................................... 13
3.1. DESIGN CONSIDERATIONS AND ASSUMPTIONS .............................................................................................. 13
3.2. DESIGN OPTIONS .................................................................................................................................... 14
3.3. PROPOSED DESIGN/ TECHNOLOGY ............................................................................................................. 15
3.4. DETAILED COMPONENTS .......................................................................................................................... 17
3.5. MINIMUM DEVELOPMENT OBLIGATIONS ..................................................................................................... 23
3.6. MINIMUM SERVICE OBLIGATIONS ............................................................................................................... 25
4. PROJECT FINANCIALS ............................................................................................................................ 26
4.1. METHODOLOGY ..................................................................................................................................... 26
4.2. DEMAND ESTIMATION ............................................................................................................................. 26
4.3. PROJECT COST BREAKUP .......................................................................................................................... 28
4.4. REVENUE ASSUMPTIONS .......................................................................................................................... 29
4.5. OPERATING ASSUMPTIONS ....................................................................................................................... 29
4.6. PROJECT FEASIBILITY ............................................................................................................................... 29
5. ANNEXURE ........................................................................................................................................... 30
5.1. REVENUE COMPUTATIONS........................................................................................................................ 30
5.2. INDICATIVE P&L STATEMENT .................................................................................................................... 32
5.3. PROJECT PROFITABILITY COMPUTATION ....................................................................................................... 33
Design, Engineering, Development, Construction, Testing,
Commissioning, and Operation & Maintenance of a
Ropeway System at Kotappakonda Temple in Andhra
Pradesh under Public Private Partnership (PPP) Mode
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1. INTRODUCTION
1.1. OBJECTIVE OF THIS PROJECT REPORT
The Department of Tourism, Government of Andhra Pradesh, proposes to develop an aerial
ropeway on Kotappakonda Hill, on Public Private Partnership (PPP) basis. The site of the
project, Kotappakonda temple on Kotappakonda Hill, is situated in Guntur district, in the State
of Andhra Pradesh. Approximately 5,000 tourists and pilgrims visit the holy site each day, and
approximately one lakh per day during the festival of Mahashivratri (in February-March).
Since the temple is difficult to access via the stairs, especially for differently abled, infirm and
aged visitors, an aerial ropeway to facilitate access to the temple, to be setup on a public
private partnership basis has been proposed. In addition to facilitating ease of access, the
ropeway would also promote the destination for religious tourism, and enable integrated
development of the project site, in line with the overall tourism developmental vision of the
Government of Andhra Pradesh.
This project report has been prepared to analyze the techno-commercial feasibility of the
aerial ropeway and provide an overview of the investment opportunity in this project.
1.2. EXECUTIVE SUMMARY
1.2.1. PROJECT SYNOPSIS
The project proposed is installation, commissioning and operations of an aerial ropeway in
Kotappakonda. Kotappakonda is situated in the Guntur District of Andhra Pradesh and is
famous for its Shiv temple.
The temple receives close to 5,000 pilgrims daily with the numbers doubling or even trebling
in the month of November. The peak season for tourist footfall is the Mahashivratri week
when more than 2 lac pilgrims visit the temple.
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The Government is now focusing on leveraging this high tourist footfall to develop additional
attractions in and around the area. The Aerial Ropeway is one such attraction which would
not just make the access to the temple easier, but also act as a local tourist attraction.
1.3. PROJECT DETAILS
1.3.1. PROJECT SITE
The main project components which require land are provided below.
1. Lower Terminal Station
2. Upper Terminal Station
3. Towers
The lower terminal station is proposed to be located at the entrance to the Ganpathi temple.
The Revenue Department has already allotted Ac.1.00Cents Land in Survey.No. 290 of the
village Kondakavaru. For the upper station, the land will be provided by the Endowments
Department for an extent of Ac.0.60 Cents near the Nandini guesthouse. Details for land site
are provided in subsequent sections.
FIGURE: SITE LAYOUT
The land for the lower terminal, upper terminal and towers shall be provided by the
Government of AP for a period of 20 years on lease, subject to the Public Private Partnership
guidelines of the State of Andhra Pradesh.
Upper terminal
Lower terminal
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1.3.2. PROJECT TECHNOLOGY
The bare minimum design of the ropeway system that has been assumed for the purposes of
this project is a pulsating jigback (fixed) installation. However, given the seasonality of the
demand at Kotappakonda, the financial feasibility has been undertaken assuming a
monocable jigback system with detachable gondolas. The project developer, based on his cost
and demand analysis, may choose to propose a more technically feasible aerial ropeway
technology as well if he so chooses, provided it be technologically superior to a pulsating
jigback (fixed) installation.
The reasons for selection of the Monocable Jigback System (Fixed) as a minimum design
system is elaborated in subsequent sections.
1.3.3. PROJECT COST
The total civil works estimates with the estimated components and prepared conceptual
layout amounts to INR 3.73 cr. The Plant and Machinery estimates for a monocable jigback
system amount to approximately INR 6 cr. The indicative cost heads are as follows:
Cost Head Amount (INR)
Civil Works (Upper and Lower stations) 37,373,372.36
Plant & Machinery (Upper/Lower stations & Towers) 60,000,000
Total Project Cost 97,373,372.36
1.3.4. PROJECT MEANS OF FINANCE
The Project is assumed to be financed by 100% promoter funding, with no funding from
commercial banks envisaged.
1.3.5. KEY PROJECT APPROVALS & REGULATORY FRAMEWORK
An indicative list of the key project approvals and clearances is provide in the table below.
The same are detailed in subsequent sections of this report.
S.No. Description of Parameter
Applicable Standards Remarks
1. Development Controls and regulations
Andhra Pradesh Building Rules – 2012 issued vide G.O. Ms. No. 168 by MA&UD, Dt. 07.04.2012 and amendments thereon from time to time and
Any other applicable regulations/stipulations, of any other statutory authorities applicable in the Local Body.
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S.No. Description of Parameter
Applicable Standards Remarks
National Building Code (NBC).
2. Spatial planning and architectural design guidelines
Urban Development Plans Formulation & Implementation guidelines (UDPFI) and Time Saver Standards.
Any other applicable regulations/stipulations, of any other statutory authorities.
3. Facilities for Persons with Different Abilities (Differently Abled Persons)
Persons with Disabilities Act, 1995 with subsequent amendments and ‘UN Convention for Rights of Persons with Disabilities (UNCRPD).
Any other applicable regulations/stipulations, of any other statutory authorities.
4. All Pavements, Roads and Signage
Indian Road Congress (IRC) & Ministry of Road Transport and Highways (MORTH) specifications.
Any other applicable regulations/stipulations, of any other statutory authorities.
5. Building construction including structures, utilities, infrastructure facilities, etc.
National Building Council (NBC) regulations.
Any other applicable regulations/stipulations, of any other statutory authorities.
6. Fire Protection and Detection Services.
National Fire Protection Authority (NFPA) regulations.
Any other applicable regulations/stipulations, of any other statutory authorities.
7. Performance Standards ISO 9001: 2008 Any other applicable regulations/stipulations, of any other statutory authorities.
1.3.6. PROJECT RECOMMENDATION
The overall installation cost of the aerial ropeway system has been estimated at INR 9.73
crores with approximate monthly operations expenditure of INR 20 lacs per month. The
demand estimations have been done based on the actual footfall numbers shared by the local
district officials of Government of Andhra Pradesh.
Considering a user charge of INR 50 one way, it is estimated that the project will have an IRR
of 19.6 % and a NPV of INR 69.40 mn across the lease period.
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2. PROJECT DETAILS
2.1. PROJECT BACKGROUND
2.1.1. BACKGROUND
Kotappakonda, also the temple known as the earthly abode of Lord Shiva, is situated in Guntur
District of Andhra Pradesh. It is believed that the temple was built prior to 1172 A.D. in the
Trikoota Hills in Guntur District. Given its age old reverence and the importance of the temple
in the local folklore, the temple receives large number of visitors on a daily basis. There are
two main ways to access the temple. One is via a road access built to the temple and the other
is via foot, the latter being the more popular one.
An aerial ropeway was proposed on a public private partnership basis to facilitate access to
the temple apart from developing it as a tourist attraction or activity. A detailed overview of
the current state of the project is provided below.
2.1.2. CURRENT STATE
The temple is located in the Trikoota Hills of Kotappakonda, previously known as
Kondakavuru. The hills are named after the Hindu God Trilogy, Brahma, Vishnu and
Maheswara, host the temple. The deity established in the shape of a Sivalinga at the hill top
is known as Trikoteswara. The deity is located at a height of approximately 1,587 feet.
There are two modes of access to the temple. A “ghat” road for vehicular traffic leading up to
the temple, with sufficient parking space at the temple site is present. The road is
approximately 30 ft. wide, with two lanes for traffic. This road has been constructed to ease
the climbing and allow the pilgrims take in and enjoy nature's bounty in its full splendor, in
place of an arduous climb up the steep steps and also to accommodate the growing number
of visitors. The entire stretch of the road is lighted and a deer park has been developed on
the way.
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The second mode of access are a thousand steps to the temple, which are steep and difficult
to navigate.
Since these three modes are insufficient to cater to the growing number of visitors, a third
option of an aerial ropeway has been proposed. Apart from ease of access and enhanced
capacity, the aerial ropeway will also catalyze tourist growth and promote Kotappakonda
temple as a tourism destination.
The development of the area is being done in an expedited manner to focus on
entertainment, devotion and spiritual aspects of a tourist. Some of the current features of the
area and temple region are as follows:
a) View Point: A View Point has been created on the corner of the hill to provide a
breathtaking overall view of the surroundings
b) Lakes and Ponds: There are multiple lakes and ponds in the
region, most notable of which are the 8 ponds situated right
in front of the temple. Additionally, a small lake has been
created on the hill, depicting the statue of Lord Krishna with
special lighting effects in the middle of the lake. Water flows
into the lake from various watershed programs developed at
many places on the hill, a blend of modernity with the past
c) Deer Park: The road stretch to the temple is an all-weather, well-lit road. Alongside the
road, a deer park has been developed as an attraction for the visitors
d) Jurassic Park: Another attraction for the tourists is the
artificial Jurassic Park with mobile dinosaurs of
monstrous size
e) Accommodation: The area has four our VIP guest houses
and a 30-room resting house for the visitors
f) Meditation Centre: An integrated tourist project is the
meditation center, built on the top of the hill and an
exclusive "Yaga Shala" for conducting 'homam' (holy fire) with a sprawling dining hall
g) Proposed Museum: A museum has been proposed to house the artefacts that were
discovered in the excavations in and around the area.
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2.2. LOCATION AND DEMOGRAPHIC DETAILS OF THE REGION
2.2.1. DISTRICT INFORMATION
Kotappakonda Hill, on which the temple is situated is located in Guntur District of Andhra
Pradesh. Guntur District is located along the east coast of Bay of Bengal. Guntur City is the
largest city in the district and the administrative center of Guntur District. The district is a
major center for learning and Telugu and Urdu are the main languages spoken here.
The geographical co-ordinates of Guntur District are 16.20°N 80.27°E. It has an average
elevation of 33 metres (108 ft) and the topography comprises mainly of plains. There are a
few hills in the surrounding suburban areas. Guntur city is located around 40 miles (64 km) to
the west of the Bay of Bengal. The Krishna Delta lies partly in Guntur district. There are other
smaller rivers and channels in the region such as Guntur Channel, Chandravanka, Naagileru,
Guntur Branch Canal etc.
Some key statistics of the district are:
Area: 11391 Sq. km. Population: ~44 lacs Urban:Rural::1:2.5
Urbanization: 28.90% Major Sectors: Agriculture & allied activities
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2.2.2. PROXIMITY INFORMATION
Guntur has always been a major location in Andhra Pradesh but more so in the divided State
as the proposed new capital of the State is in Guntur. This gives the district the strategic
advantage of focus and prioritization in all Government Schemes especially w.r.t.
infrastructure development. Guntur has always been well connected to the State and to other
parts of the country.
a) Road Network: Guntur is well connected to all major cities of the country through
National and State Highways. NH5 that runs from Kolkata to Chennai, passing through
Guntur city is a part of AH 45 which comes under the Asian Highway Network. The
Hyderabad – Nalgonda- Guntur is a State highway connecting Hyderabad with Guntur
city. It passes through Nagarjuna Sagar, a famous tourism destination. Regarding
Kotappakonda, the nearest town located close to the proposed project site location,
is Narasaraopet. It is about 50 Kms from Guntur City, 90 Kms from Vijaywada and 350
Kms from Hyderabad.
b) Rail Network: Narasaraopet is well connected from Guntur by train as well with
multiple trains throughout the day. It is a two hour train ride from Vijayawada.
c) Air Network: Visitors can also fly to Vijaywada Airport and from there leave for
Narasaraopet using road or rail networks.
2.2.3. DEMOGRAPHIC AND OTHER INFORMATION
The district covers an area of 11,391 Sq.km, comprising of a population which is
predominantly rural. The Krishna River forms the northeastern and eastern boundary of the
district, separating Guntur District from Krishna District. The district is bounded on the
southeast by the Bay of Bengal, on the south by Prakasam District, on the west by
Mahbubnagar District, and on the northwest by Nalgonda District. Administratively, it is
divided into 57 mandals.
a) Social Information
Guntur has a total population of 44 lacs with almost equal sex ratio (22 lac males for 21.85 lac
females). The region is primarily rural given that Agriculture and allied activities are the largest
employer and the largest contributor to the District’s local economy.
Nearly 48% of the total population constitutes of workers of which nearly 73% work in
Agriculture and allied activities.
b) Economic Information
Guntur is a center of learning and the administrative capital of Guntur district, which is home
of historically significant Amaravati, Bhattiprolu and Sitanagaram monuments. The city is also
a center for business, industry, and agriculture. The region is identified as a major
transportation and textile hub in India. Additionally, the Guntur area economy has an
agricultural component that is internationally known for its exports of chillies, cotton, and
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tobacco. The district’s economy has been growing steadily and was at INR 41,000 crores in
2012-13 with a per-capital income of INR 79267, both at current prices.
The district is next only to Vishakhapatnam and Chitoor in terms of large and mega
investments. During 2013-14 alone, 6 such projects were approved with an estimated
investment outlay of INR 190 crores.
c) Climate
Guntur experiences primarily a hot season throughout the year, summer being extremely
warm. December till February is a dry and cool winter season. March to May is the warm
summer season, and June to September being the months when the South-West monsoon
approaches. October till November is the post monsoon or retreating monsoon season.
Storms and depression, originating in the Bay of Bengal, cross the east coast of the district
causing wide spread heavy rain and strong winds. Thunder-storms occur during March-
October, being more frequent in the post-monsoon season.
2.3. PROJECT SITE
Kotappakonda is a major religious destination in not just Guntur but also in Andhra Pradesh.
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2.4. PROJECT NEED
The holy temple is the focal point for pilgrims across the State and neighboring States, who
wish to pay homage to Lord Shiva at the temple. Approximately 3,000-5,000 tourists and
pilgrims visit the holy site each day, and approximately one lakh during Mahashivratri. Since
the temple is difficult to access via the stairs, especially for differently abled, infirm and aged
visitors, the Department of Tourism proposed an aerial ropeway to facilitate access to the
temple, to be setup on a public private partnership basis.
In addition to facilitating ease of access, the ropeway would also promote the destination for
religious tourism, and enable integrated development of the project site.
2.5. STAKEHOLDER ANALYSIS
The entire lifecycle of the project will have many interacting stakeholders whose needs/
requirements/ concerns would need to be addressed. Some of these stakeholders are:
a) Endowments Department/ Temple Staff: The various people working to make the
temple and the surrounding area functional including stakeholders from Endowments
Department of GoAP would be constant partners in this journey. Given their hands on
experience of the temple, the entire project planning exercise would have a
representation from them as well so that their knowledge and concerns can be taken
into consideration right from project initiation
b) Tourists: The biggest beneficiaries of the project will be the tourists/ pilgrims coming
to the temple. An appropriate balance would need to be struck between user charges
and technology used so that while the aerial ropeway rides are feasible, there should
be no compromises on safety as well
c) GoI Entities: Government of India has released guidelines for implementation of aerial
ropeway projects and those would have to be kept in consideration during detailed
designing and implementation of the project. These include the guidelines issued by
Bureau of Indian Standards (BIS) and Ministry of Environment and Forests (MoEF),
Government of India
d) Tourism Department: Last but not the least, the project shall be owned by the Tourism
Department of Andhra Pradesh with respect to State and Department level project
approvals, project review, selection of implementation agency and ensuring overall
success of the initiative.
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3. PROJECT DESIGN
According to the technical definition of the Indian Bureau of Technical Standards, an “aerial
ropeway is a special form of transportation system where passengers/materials are carried
above the ground. A ropeway uses a tensioned wire rope supported above the ground. Aerial
ropeways are particularly useful in regions where the facility in surmounting natural barriers
gives them a great advantage over railways or roads, both of which may need the heavy civil
engineering work to secure easy gradient. They are inexpensive to maintain; pollution free;
environment friendly; requires minimum tree cutting; does not affect aesthetics; their power
demand is modest; and, they are not seriously affected by adverse climatic conditions”.
3.1. DESIGN CONSIDERATIONS AND ASSUMPTIONS
The design requirements/ principles which have been kept in consideration while designing
the project. These include:
a) Design of the Aerial Ropeway shall be strictly in line with the guidelines issued by Bureau
of Indian Standards, MoEF (GoI) and any other guidelines issues by Central/ State
Government
b) The structure and the overall system should be built considering the climate in the region
c) An appropriate balance needs to be maintained in the cost of the ropeway system selected
and the ability to carry maximum tourists. It needs to be borne in mind that Kotapakonda
is primarily a religious destination
d) The numbers considered for design evaluation are approximate and based on on-ground
information provided by GoAP officials.
It has been estimated that every day an estimated 5,000 tourists visit the temple every
day, except Tuesday and Wednesdays when the numbers reduce to 1,000 tourists only
Mahashivratri is the biggest festival in the region and the numbers during this time
increase to approximately 50,000 tourists per day for 3 days preceding the day of
festivals, about 1,00,000 tourists on the day of the festival and about 50,000 the day
after the festival. This is a once in a year event.
Similarly, November is an auspicious month for the temple visitors and the number of
tourists per day in November can go upto 10,000.
It has been assumed that of the total number of tourists coming to Kotappakonda
temple, only about 30% would opt for the aerial ropeway to reach the temple or come
back from the temple or both.
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3.2. DESIGN OPTIONS
The first aerial tram was built more than 350 years ago but this method of moving people and
goods popular in 1800s only. Since then, many systems of aerial ropeways have been
implemented based on the project’s needs and salient features. These include cost factors,
terrain, carrying capacity, rate of transfer and climatic conditions. In the case of
Kotappakonda, there are three ropeway systems which will best suit the requirements. These
include:
A. Monocable ropeway system
B. Bicable & Tricable ropeway systems
C. Jigback system (Monocable)
These ropeway systems are analyzed in detail below.
A. MONOCABLE ROPEWAY SYSTEMS
A Monocable ropeway System comprises basically of a rope which acts both as the carrying
as well as the haulage rope to which a number of vehicles (carriages) are attached at regular
intervals. These vehicles circulate around the closed system by continuous carrying-cum-
haulage rope. The vehicles can be in the form of chairs or gondolas (enclosed carriers, also
referred colloquially as cabins). Usually the carrying capacity of each vehicle varies from 2
passengers to 8 passengers.
Monocable can be either fixed grip or detachable grip. Fixed grip installations are the types
of ropeways whose grip is permanently fixed and tight on the rope and is not taken off the
rope in the station. Detachable installations are characterized by the possibility of detaching
the vehicles in the stations from the rope. This enables a higher speed on the line, a lower
speed in the station and makes the boarding and de-boarding more comfortable for the
passengers. According to this, a significantly higher transport capacity as well as more comfort
for the passenger can be achieved. Fixed grip installations are more inexpensive to install than
detachable grip installations.
Capital Costs Operating Costs Carrying Capacity Overall Suitability
B. TRI - BICABLE ROPEWAY SYSTEMS
This Ropeway System consists of two/three stationary carrying track ropes with connecting
rails and a single endless haulage rope. The support cables are terminated at the two end
terminals with one end provided with a counter weight / hydraulic tension unit for
extension/contraction. A number of carriages are automatically coupled to or uncoupled from
the haulage rope at the station and are transported on the rails for boarding/de-boarding of
passengers. Multiple cable solutions offer differentiating advantages from a technical
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perspective. They guarantee increased wind resistance and are also able to cross spans of
over 2,500 meters. This makes for a perfect application over steep and exposed terrain.
Tricable gondola lifts have one hauling cable and two support cables. In both systems, grips
are detachable, meaning that the systems have a very high transport capacity.
This system has high transport capacity up to 6,000 people/h (cabins can carry upto 35
people) with speeds upto 8 m/s
Capital Costs Operating Costs Carrying Capacity Overall Suitability
C. JIGBACK SYSTEM (MONOCABLE)
It is possible to combine the characteristics of a Monocable system and a Jig Back System.
Such a system has a carrying-cum-haulage rope to which one or a group of cabins are attached
in either direction, attachment being made on diametrically opposite side of the carrying-
cum-haulage rope. In addition, both of these sub-categories individually can be either be
“normal systems”, or “pulsating systems”. In normal systems the vehicles (cabins) travel and
enter the station evenly, while in pulsating systems a group of vehicles travels and
enters/exits the terminal station for passenger embarking/disembarking. Pulsed
configurations are mainly employed for relatively short ropeways.
The Jigback system is simple to operate and less expensive, and is ideally suitable for hilly,
undulating terrain. The capital expenditure investment in this system is also relatively low,
and is comfortable for the passengers to embark/disembark and ride. The carrying capacity
can also be augmented based on increase in demand. This system has relatively less carrying
capacity than the other system categories. Transport capacity upto 100 - 500 PPH depending
on the route & length.
Capital Costs Operating Costs Carrying Capacity Overall Suitability
3.3. PROPOSED DESIGN/ TECHNOLOGY
The selection of appropriate ropeway system for the project depends on the following factors:
i. Carrying capacity for which the ropeway system needs to be designed
ii. The topography of the project site
iii. Investment and operating cost required
iv. Comfort factors for the passenger
v. Speed of cabins
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Taking into account all these factors, the Jigback Monocable (Fixed) is the minimum system
for the proposed ropeway. The summary of cabin movement is as follows:
The carrying cum haulage rope, which will support as well as move the cabins
along the ropeway, is attached to two terminals, known as the Upper terminal
and Lower terminal. The ropeway is supported by towers along the way. The
group of cabins of 6 passengers’ capacity each will be attached to at opposite
ends of the ropeway. The passengers will embark/disembark when the cabins
are stationary at the terminals. After the loading/unloading of passengers, the
station manager will give the green signal and the cabins will move out of the
station and obtain the desired speed. While approaching the opposite terminal,
the “Drive” is slowed down, and the cabins halt at the terminal station. After
loading/unloading, the drive is reversed. While one group of cabins goes up, the
second group comes down in the same manner. The system is designed keeping
in mind the safety parameters as laid down in Indian standards.
Pulsating Jigback Monocable (Detachable) was also evaluated and best meets the balance of
techno-commercial feasibility. The advantages of this ropeway system are as follows:
i. This system is designed for a lower range of carrying capacity, and is suitable for
carrying 400 passengers/ hour (demand capacity envisaged for Kotappakonda temple)
ii. The proposed project region does not have extreme weather conditions such as high
wind factors, excessive rain etc. which makes this system suitable.
iii. The investment in this project system at approximately INR. 9.73 cr. is relatively lower
than other systems, and is justified by the return on investment and project IRR.
In Monocable Jigback
System (detachable)
system, the station’s
gondola structure will
include an area where each
cabin will be detached from
the ropeway; decelerated
to a speed slow enough for
boarding and
disembarking; and then
accelerated, allowing for the reattachment. Therefore, disembarking and boarding will take
place in separate locations on the platform. Similarly, at intermediate angle stations, each
gondola will detach from one cable and subsequently attaches to another cable that is aligned
in a different direction.
Developer, as part of the proposal, may choose to propose one of the above ropeway systems
or may propose a better ropeway system (like bi cable or tri cable) based on their own
assessments.
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Commissioning, and Operation & Maintenance of a
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Pradesh under Public Private Partnership (PPP) Mode
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3.4. DETAILED COMPONENTS
The Pulsating Jigback Monocable is one of the most popular aerial ropeway systems
worldwide for transporting passengers. It consists of various sub-components including, but
not limited to, the following:
A. Cabins
Cabins are the structural and mechanical assemblage in which the passenger(s) of a ropeway
system are transported. The cabin includes the carriage/ grip, hanger, and the passenger
cabin. The cabin will consist medium cabins which can seat 6-8 people. The cabins will be
totally enclosed and have a standing room to reach full capacity.
B. Terminals/ Stations
The system will have two terminals: Upper and Lower terminals. The drive machinery may be
installed overhead or in an underground vault, based on developer’s design and land allocated
at upper and lower terminals at the project site.
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Lower Terminal Station
SITE LOCATION OF LOWER STATION
The station at the base of Kotappakonda Hill will be the lower terminal station. The land site
is adjoining a pond, and comprises of a few trees and shrubbery. The survey layout of the
lower terminal station is provided in the figure above. For the Lower station, Sy.No. 290 of
the village Kondakavaru of Narasaraopet Mandal has been identified. It is to be noted that
the Tourism Department of Government of Andhra Pradesh is in the process of receiving
possession of/ permission to undertake project construction in the land for lower terminal,
right of way and upper terminal. This report has been prepared based on the assumption that
the process shall be completed successfully.
For preparing the site at the lower station, an indicative list of bill of quantities for civil
works has been provided below:
S. No Description Units Quantity Rate (INR) Amount (INR)
1
Jungle clearance and up routing of the Light jungle and burnt in to ashes as directed by the Engineer - In - Charge including cost and conveyance of all materials and Labour charges etc. complete
Sft 43632.00 2.00 87264.00
2 Provision for Deck with all provisions
Sft 3499.20 2000.00 6998400.00
3 Providing Ticket counter Sft 32.40 1750.00 56700.00
4 Provision for Information Deck Sft 43.20 1750.00 75600.00
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Commissioning, and Operation & Maintenance of a
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S. No Description Units Quantity Rate (INR) Amount (INR)
5 Providing for WorkShop Sft 874.80 1750.00 1530900.00
6 Provision for Store Room Sft 307.27 1750.00 537727.68
7 Provision for Spare Room Sft 124.26 1750.00 217463.40
8 Provision for Waiting Lobby Sft 440.32 1750.00 770553.00
9 Provision for Security Check Sft 186.62 1750.00 326592.00
10 Provision for Coffee Shop Sft 1555.20 1750.00 2721600.00
11 Provision for Toilet Sft 486.00 1000.00 486000.00
12 Provision for landscaping LS 1000000.00
13 Provision for Seating arrangement LS 375000.00
14 Provision for children’s play equipment
LS 1000000.00
15 Provision for Compound wall Rm 271.27 6500.00 1763268.00
16 Outside yard development LS 3000000.00
Sub Total 20947068.08
Upper Terminal Station
SITE LOCATION OF UPPER STATION AT KOTAPPAKONDA TEMPLE
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For the upper station, the land will be provided by the Endowments Department for an
extent of Ac.0.60 Cents
For preparing the site at the lower station, the indicative list of bill of quantities for civil
works has been provided below:
S.No Description Units Quantity Rate (INR)
Amount (INR)
1
Jungle clearance and up routing of the heavy jungle and burnt in to ashes as directed by the Engineer - In - Charge including cost and conveyance of all materials and Labour charges etc. complete
Sft 2700.00 70.00 189000.00
2
Removing the Hard Rock cutting using with Mechanical meanse as directed by the Engineer - In - Charge including cost and conveyance of all materials and Labour charges and the burning chemicals tec. Complete
Cum 506.25 500.00 253125.00
3
Provision of RCC Retaining wall with RCC (1:3:6) nominal mix proportion with cement coping at the top and provision of weep holes for the dissipation of the energy including all labour charges etc. complete
Cum 150.00 6000.00 900000.00
4
Filling with Suitable soils in between the Retaining walls and compacting the soils with 95% of relative density in layers not less than 150 mm thick layers with 8 to 10 tons power roller including cost & conveyance of all labour and material charges etc.
Cum 800.00 650.00 520000.00
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S.No Description Units Quantity Rate (INR)
Amount (INR)
5
Supply and placing of the Design Mix Concrete M 20 grade corresponding to IS 456 with minimum cement content of 380 kgs per 1 cum of concrete and required quantity of Chemical Admixtures per 1 cum of concrete using batching and mixing plant of 15cum to 20cum capacity per hour with 20mm size graded machine crushed hard granite metal (coarse aggregate) ( consisting of nominal size metal 60% of 20mm , 15% of 13.20/12.50mm , 15% of 10mm and 10% of 6mm ) from approved quarry including cost and conveyance of all materials like cement, fine aggregate (sand) coarse aggregate, water etc., to site and including Seigniorage charges, sales & other taxes on all materials , centering , shuttering, scaffolding with props and steel plate as per the approved shuttering plan and other accessories as per the norms and stability calculations including hire, operational & crew charges of batching and mixing plant & transit mixer, laying concrete, curing etc., and overheads & contractors profit complete but excluding cost of steel and its fabrication charges for finished item of work for Grade slab
Cum 50.25 8350.00 419587.50
6
Supplying, fitting and placing HYSD (Fe 500/ tmt grade as per IS 1786-1985) bar reinforcement in foundation complete as per drawings and technical specifications for Bars below 36 mm dia including over laps and wastage, where they are not welded including cost and conveyance of bars from approved sources to site of work, binding wire, cover blocks and all incidental, operational, labour charges such as cutting, bending, placing in position, tying etc., and sales & other taxes, on cost of all materials complete for finished item of work
MT 10.05 46000.00 462300.00
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Commissioning, and Operation & Maintenance of a
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S.No Description Units Quantity Rate (INR)
Amount (INR)
7 Provision for Deck Sft 3499.20 500.00 1749600.00
8 Provision for Ticket counter Sft 32.40 1750.00 56700.00
9 Provision for Information Deck Sft 43.20 1750.00 75600.00
10 Provision for landscaping LS 400000.00
11 Provision for Seating arrangement LS 75000.00
12 Provision for Shed with Corrugated GI sheets with all necessary provisions
Sft 2700.00 950.00 2565000.00
13 Provision for substructure to with stand heavy towers (approx 3 towers)
Cum 168.75 10500.00 1771875.00
Sub Total 9437787.50
The overview of the total civil works cost is provided below:
C. Towers
Towers are intermediate structures that support the
track and haulage ropes between terminals. They
are often steel framed, and are sometimes pylon-
shaped. The tower’s primary function is to support
track ropes and haulage ropes on saddles and line
sheaves respectively. Towers must also have guides
to keep carriages from hitting them for safety.
Towers might not always be necessary depending
on the length of the system. For long systems,
intermediate towers are necessary to provide support to the system and therefore
Cost Head Amount
Total of Civil Work for Lower Station 20947068.08
Total of Civil Work for Upper Station 9437787.50
Civil Work Cost 30384855.58
Departmental Sattuary provisions
(21% of the Estimated cost)6380819.67
Provisoin for unforeseen items of the work @ 2% 607697.11
Total Civil Work Cost 37373372.36
Design, Engineering, Development, Construction, Testing,
Commissioning, and Operation & Maintenance of a
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eliminating the need for long spans. A minimum of two towers will be required for the aerial
ropeway.
D. Ropes/ Cables
The rope (cable) is the heart of any Aerial Ropeway Transit system. It is formed by inter-
twining individual wires to form a strand and then the strands to form a rope. There are many
variations of the processes used in manufacturing ropes and in choosing the appropriate rope
for any given application.
E. Plant and Machinery
The minimum components of the Plant and Machinery will be a main drive, an auxiliary drive,
main gear box, tension trolley, counter-weight trolley, grip system, etc. The developer needs
to ensure adherence to the minimum service obligations. T
3.5. MINIMUM DEVELOPMENT OBLIGATIONS
The developer shall construct, operate, maintain and manage the proposed facility strictly
conforming to the relevant Indian Standards; the best industry practices acceptable norms as
laid by Ministry of Tourism, GoI as well as the minimum service obligations. These
development obligations are defined below.
1. Site Development Guidelines
i. The internal paving may be done using recycling waste/ eco-friendly materials
that helps the environment.
2. Civil, Structural & Environmental Requirements
i. The structures shall be designed to resist wind and seismic forces.
ii. RCC structures shall be designed as per IS 456: 2000.
iii. Steel structures shall be designed in accordance with the provisions of IS 800:1984.
Structural steel shall conform to IS 2062:2006. Tubular sections would conform to IS-
4923. Structural joints shall conform to IS 4000:1992.
iv. Mitigation measures to be considered to reduce the negative impact on the ecology,
available resources on site, soil erosion, existing vegetation and habitat, water and air
pollution and waste handling as per the Manual on norms and standards for
environment clearance of large construction projects.
v. Developer is advised to carry out its own tests and investigations related to soil
condition, strata, bearing capacity and other characteristics.
vi. All buildings shall be designed and constructed as earthquake and flood resistant
structures.
3. Services: Electrical, Water Supply, Plumbing, Drainage and Solid Waste Management
i. The planning, design and execution of electrical installation, ventilation, air-
conditioning, shall be carried out in accordance with Part VIII-Building Services (Section
2-Electric Installations, Section 3-Air Conditioning) of National Building Code of India
Design, Engineering, Development, Construction, Testing,
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prepared by BIS and as prevalent at the time of execution of the works, as the case may
be.
ii. The planning, design, construction and installation of water supply distribution system,
drainage and sanitation shall be in accordance with the Part IX (Section 1-Plumbing
Services, Section 2-Plumbing and Sanitation, Section 3-Gas Supply as the case may be)
of NBC of India prepared by BIS and as prevalent at the time of execution of the work.
iii. Solid Waste Collection and Disposal System shall be in place by implementation of
environmentally sound solid waste collection mechanisms.
iv. The Project site shall be maintained as “Plastic Free Zone”.
v. Maintain the natural areas and indigenous vegetation to extent possible;
vi. Retain the natural drainage characteristics;
vii. Incorporate Energy efficient designs & utilities;
viii. Efforts shall be made for Water Conservation by implementing innovative
practices such as Rain water harvesting methods
ix. Usage of non-polluting internal transport system such as battery operated cars
etc.
4. Power Supply
i. Developer may explore more of non-conventional/renewable energy sources of power
supply like solar, wind etc. to match the theme of eco-friendly development.
ii. The Developer shall ensure:
a. Un-interrupted power supply to the Project Components;
b. Adequate earthling provisions for total protection of equipment;
c. 100 % backup through requisite number of DG sets as stand-by
5. Fire Fighting Facilities
The Developer shall provide the required fire-fighting equipment and facilities including fire exits,
fire proof doors, etc. conforming to the relevant BIS standards.
6. Rain Water Harvesting
The rainwater harvesting shall be adopted as per the rules and regulations laid down by the
statutory law applicable for the concerned area.
7. Facilities for Physically Challenged Persons
The Developer shall provide necessary arrangements for disabled / physically challenged persons
for accessing project facilities.
8. Signages
The Developer shall provide signages so as to facilitate necessary information to the visitors
regarding amenities and their location. The signage would be provided separately;
i. Information Signs,
ii. Facility Signs, and
iii. Other Signs
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9. Parking Area
As per the demand, the developer shall provide parking facilities for the visitors of the proposed
project. In that case the specifications to be followed are as below:
10. Access within the Site
a. The main access to any component shall have adequate width not less than 7.5 m.
b. An unobstructed area of minimum width of 3 m. shall be provided around each built structure
in the premise for Fire Tender movement. This shall be within the limit of the site and shall
be paved with impervious material above a hard bed.
All the above are minimum requirements subject to the norms of fire services department
11. Supporting Facilities and Amenities
The developer shall provide all the necessary supporting facilities and amenities confirming to the
development controls and meeting the relevant Indian standards.
3.6. MINIMUM SERVICE OBLIGATIONS
The developer should ensure adherence to the minimum service obligations. The minimum
service obligations are defined, but are not limited to the following:
1. Pre-operative checks
The daily pre-operative checks should be conducted on the machinery. These include but
are not limited to gear box oil checks, whether there is wobbling in the splicing ear,
checking of auxiliary drive and main drive, checking for vibration above defined levels in
tower etc.
2. Post-operative checks
There should be a preventive maintenance schedule prepared, and maintenance on the
plant and machinery should be conducted once a month. Major maintenance and repair
should take place monthly. BIS standards must be mandatorily followed for all plant and
machinery equipment.
These obligations are only indicative in nature, and the developer must ensure the safety
and security of passengers.
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4. PROJECT FINANCIALS
4.1. METHODOLOGY
The methodology adopted to arrive at the feasibility of the proposed aerial ropeway project
factors in the fact that significant constraints exist for arriving at an absolutely accurate
number of visitor’s (both pilgrims and tourists) to Kotappakonda temple. The visitors at the
temple are not recorded officially, and since lakhs visit on Mahashivratri it is physically and
administratively difficult to record the number of arrivals.
Keeping these constraints in mind, data from administrative officials of the Tourism
Department stationed on-site has been obtained. Certain simplifying assumptions have been
used to arrive at the key metric used in analyzing feasibility.
4.2. DEMAND ESTIMATION
As per data obtained, visitor arrivals at Kotappakonda exhibit seasonal patterns, depending
on festival time (peak season) and normal season (off-peak season). The visitor footfall peaks
in the last week of February, during the festival of Maha Shivratri, and during November,
during the festival of Kartik Maas. Hence, the off-peak season has been defined as the time
period during all the months in a year except February and November. The peak season is
during the month of February and November. Data on collection of visitor footfalls to the
Kotappakonda temple is exhibited below:
Visitor Arrival Schedule Per Week (off-peak season)
Weekly Arrivals during off-peak season
Mon Tues Wed Thurs Fri Sat Sun Weekly
Total
5000 1000 1000 5000 5000 5000 5000 27000
The approximate weekly visitor footfall during the off-season is ~27000. There are ten months
in the off-peak season.
4.2.1. TOURIST ESTIMATIONS
The daily operating hours of the ropeway are assumed to be 10 hours, from 7:00 am in the
morning till 5:00 pm in the evening). The percentage of total visitors to the temple who would
use the ropeway is assumed to be 30% (keeping in mind that significant people come via the
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Ghat road in vehicles, and would switch to the ropeway for the enhanced touristic
experience). One day of downtime due to maintenance and repair for the ropeway system is
assumed in a month.
Passenger per hour during off-peak season computation
Passenger per hour during off-peak season computation
Weekly
Total
(A)
Monthly
Total
(A*4) = (B)
Daily
Operating
hours
(C)
No. of
Months in
the off-peak
season (D)
% of
ropeway
passengers
(E)
No. of
operating
days in a
month
(F)
Passenger / hour
during off-peak
season
[(B)*(E)]/[(F)*(C)]
27000 108000 10 10 30% 29 112
February is a critical month for the temple as Mahashivratri falls in this month. The number
of tourists in the festival week peaks by almost 5 times the normal weekly average.
Passenger per hour computation for February
Passenger per hour computation for February
Weekly
Total
(A)
Fourth Week
(Mahashivratri)
(B)
February
Total
(C)=
(A)*(3)+(B)
Hours of daily
operation
(D)
% of
Ropeway
Passengers
(E)
No. of
operating
days in a
month
(F)
Passenger per hour
during February
(G)=
[(C)*(E)]/[(F)*(D)]
27000 200000
281000
10 30% 29
291
Similarly, for the month of November, the weekly arrivals follow a different pattern due to
the festival season of Kartik Maas.
Visitor Arrival Schedule (November)
Weekly Arrivals during November
Mon Tues Wed Thurs Fri Sat Sun Weekly
Total
7500 7500 7500 7500 7500 7500 7500 52500
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Passenger per hour computation for November
November Passenger per hour computation
Weekly
Total (A)
November
Total
(B)=
(A)*(4)
Hours of daily operation
(C)
% of Ropeway
Passengers
(D)
No. of operating
days in a month
(E)
Passenger per hour
during November (F)=
[(B)*(D)]/[(E)*(C)]
52500 210000 10 30% 29
217
4.2.2. CABIN ESTIMATION
Assuming a cabin can do 5 return trips in an hour (given the distance of 1200 m and 2m/sec
average speed of the cabin), 7 cabins are required to accommodate the demand (passengers
per hour) in off peak season. Assuming a maximum design capacity of 12 cabins on the
ropeway (due to load constraints) and space for 6 passengers, at 5 return trips the maximum
number of passengers that can be transported via ropeway in an hour is 360. This forms the
ceiling of the demand estimates, for the purposes of revenue computation.
4.3. PROJECT COST BREAKUP
The Project cost breakup is provided below:
Project Cost Head % of Total project Cost Approximate cost (INR
mn)
Civil Works 38% 37.37
Plant & Machinery 62% 60.00
Total Project Cost 100% 97.37
Financial and Accounting Assumptions
1. The project cost is assumed to be financed 100% by equity finance
2. Depreciation is applied on a straight line basis
3. Corporate tax rate is 30%, with a surcharge for 10% and education-cess of 2%, it amounts
to 33.66 % approximately
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4.4. REVENUE ASSUMPTIONS
1. The Authorization agreement with the developer is assumed to be for a period of 20
years, and the cash flows of the project to arrive at the IRR is projected over this period.
Two years has been finazlied as lease period as:
a. 20 years can be considered as reasonable life of ropeway equipment which would
be installed by the developer
b. The time period is reasonable long for developer to recover costs and profits without
considering additional sources of revenue like food & beverages and advertising
2. The one way tariff (INR per passenger per trip) is INR 50.
3. This tariff is escalated at 5% per annum.
4. The escalation is passenger trips is assumed to be growing at 2% annually, given the
increase in tourist demand and benefits of the ropeway in promoting the destination for
tourists. This is subject to a ceiling of 360 passengers per hour, due to capacity constraints
mentioned above.
4.5. OPERATING ASSUMPTIONS
1. Number of operating hours is assumed to be 10 hours per day.
2. Number of operating days in a month are assumed to be 29, assuming one day of
downtime for repair and maintenance.
3. Operating and maintenance expenses (including fuel, utilities, manpower costs etc.) are
assumed to be INR 2 mn per month, escalated at 4% per annum.
4.6. ADDITIONAL DEVELOPMENT PREMIUM
The project developer shall have to pay additional development premium in way of minimum
assured revenue or % contribution of gross receipts, whichever is higher. It has been assumed
that the revenue contribution will start from end of two years from COD. It would either be
20 lacs per year, incremented at 5% per year, or 4% of gross receipts, whichever is higher.
4.7. PROJECT FEASIBILITY
Factoring in the assumptions mentioned above, the Project IRR is a robust 19.6%, indicating
a very profitable investment. The Project Net Present Value is also positive at INR 69.40 mn.
This project is commercially feasible and should be invested in, keeping in mind the
assumptions and constraints outlined above.
Project Report on Development of “Kotappakonda
Aerial Ropeway Project”
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5. ANNEXURE
5.1. REVENUE COMPUTATIONS
5.1.1. REVENUE COMPUTATION (NORMAL SEASON)
Year of Operation 1 2 3 4 5 6 7 8 9 10
Months of operation 10 10 10 10 10 10 10 10 10 10
Tariff INR 0 50 52 55 57 60 63 67 70 73
Passenger return trips/ hour No.
0 223 227 232 237 241 246 251 256 261
Hours of operation No. 2900 2900 2900 2900 2900 2900 2900 2900 2900 2900
Revenue in off season INR mn 0.00 32.40 34.23 37.00 39.18 41.93 44.94 48.77 51.97 55.25
Year of Operation 11 12 13 14 15 16 17 18 19 20
Months of operation 10 10 10 10 10 10 10 10 10 10
Tariff INR 77 81 85 89 94 98 103 109 114 120
Passenger return trips/ hour No.
267 272 277 283 289 294 300 306 312 319
Hours of operation No. 2900 2900 2900 2900 2900 2900 2900 2900 2900 2900
Revenue in off season INR mn 59.62 63.89 68.28 73.04 78.78 83.55 89.61 96.73 103.15 111.01
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5.1.2. REVENUE COMPUTATION (PEAK SEASON)
Year of Operation 1 2 3 4 5 6 7 8 9 10
Months of operation 2 2 2 2 2 2 2 2 2 2
Tariff INR 0 50 52 55 57 60 63 67 70 73
Passenger return trips/ hour No.
0 360 360 360 360 360 360 360 360 360
Hours of operation No. 580 580 580 580 580 580 580 580 580 580
Revenue in peak season INR mn 0.00 10.44 10.86 11.48 11.90 12.53 13.15 13.99 14.62 15.24
Year of Operation 11 12 13 14 15 16 17 18 19 20
Months of operation 2 2 2 2 2 2 2 2 2 2
Tariff INR 77 81 85 89 94 98 103 109 114 120
Passenger return trips/ hour No.
360 360 360 360 360 360 360 360 360 360
Hours of operation No. 580 580 580 580 580 580 580 580 580 580
Revenue in peak season INR mn 16.08 16.91 17.75 18.58 19.63 20.46 21.51 22.76 23.80 25.06
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5.2. INDICATIVE P&L STATEMENT
Year of Operation 1 2 3 4 5 6 7 8 9 10
Gross Revenues INR mn 0.00 42.84 45.09 48.49 51.08 54.46 58.10 62.76 66.58 70.50
Less: Operating & Maintenance expenses INR mn - 24.00 24.96 25.96 27.00 28.08 29.20 30.37 31.58 32.85
Gross Profit INR mn 0.00 18.84 20.13 22.53 24.08 26.39 28.90 32.39 35.00 37.65
Less: Depreciation INR mn 0.00 4.87 4.87 4.87 4.87 4.87 4.87 4.87 4.87 4.87
Less: MAR INR mn 0 2 2.10 2.21 2.32 2.43 2.55 2.68 2.81 2.95
Less: Revenue Cont. 0 1.7136 1.80 1.89 1.98 2.08 2.19 2.30 2.41 2.53
Less: Annual Land Lease Rent INR mn 0.080 0.084 0.088 0.093 0.097 0.102 0.107 0.113 0.118 0.124
Profit before Tax INR mn 0.00 11.89 13.07 15.36 16.80 18.98 21.37 24.73 27.20 29.70
Tax INR mn 0.00 3.96 4.36 5.12 5.60 6.33 7.12 8.24 9.07 9.90
Profit after Tax INR mn 0.00 7.93 8.72 10.24 11.20 12.66 14.25 16.49 18.13 19.80
Year of Operation 11 12 13 14 15 16 17 18 19 20
Gross Revenues INR mn 75.70 80.81 86.03 91.63 98.41 104.02 111.12 119.49 126.95 136.07
Less: Operating & Maintenance expenses INR mn 34.16 35.53 36.95 38.42 39.96 41.56 43.22 44.95 46.75 48.62
Design, Engineering, Development, Construction, Testing,
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Gross Profit INR mn 41.54 45.28 49.08 53.20 58.45 62.46 67.89 74.53 80.20 87.45
Less: Depreciation INR mn 4.87 4.87 4.87 4.87 4.87 4.87 4.87 4.87 4.87 4.87
Less: MAR INR mn 3.10 3.26 3.42 3.59 3.77 3.96 4.16 4.37 4.58 4.81
Less: Revenue Cont. 2.66 2.79 2.93 3.08 3.23 3.39 3.56 3.74 3.93 4.12
Less: Annual Land Lease Rent INR mn 0.130 0.137 0.144 0.151 0.158 0.166 0.175 0.183 0.193 0.202
Profit before Tax INR mn 33.44 37.02 40.65 44.59 49.65 53.46 58.69 65.12 70.56 77.56
Tax INR mn 11.14 12.34 13.55 14.86 16.55 17.82 19.56 21.70 23.52 25.85
Profit after Tax INR mn 22.29 24.68 27.10 29.73 33.10 35.64 39.13 43.41 47.04 51.71
5.3. PROJECT PROFITABILITY COMPUTATION
Project IRR computation & NPV 1 2 3 4 5 6 7 8 9 10
Capital Expenditure INR mn (97.37)
Profit after Tax INR mn 0.00 7.93 8.72 10.24 11.20 12.66 14.25 16.49 18.13 19.80
add: Depreciation INR mn 0.00 4.87 4.87 4.87 4.87 4.87 4.87 4.87 4.87 4.87
Cash Flows INR mn (97.37) 12.79 13.58 15.11 16.07 17.52 19.12 21.36 23.00 24.67
Design, Engineering, Development, Construction, Testing,
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e34
Project IRR computation & NPV 11 12 13 14 15 16 17 18 19 20
Capital Expenditure INR mn
Profit after Tax INR mn 22.29 24.68 27.10 29.73 33.10 35.64 39.13 43.41 47.04 51.71
add: Depreciation INR mn 4.87 4.87 4.87 4.87 4.87 4.87 4.87 4.87 4.87 4.87
Cash Flows INR mn 27.16 29.55 31.97 34.60 37.97 40.51 44.00 48.28 51.91 56.58
Project IRR 19.6%
over 20 years of
operation
Project NPV INR mn
69.40