2

Table of Contents

Executive Summary…………………………………………………………………………………………………………

1. Introduction……………………………………………………………………………………………………………..

2. Smart Campus Policy………………………………………………………………………………………………..

3. Demographical view of JSS Medical Institutions……………………………………………………….

4. Beginning of a Smart Campus…………………………………………………………………………………..

5. Key elements of a Smart Campus……………………………………………………………………………..

5.1. Buildings…………………………………………………………………………………………………..

5.2. Education, Learning & Digitisation……………………………………………………………

5.3. Sports & Recreation…………………………………………………………………………………

5.4. Safety & Security………………………………………………………………………………………

5.5. Waste, Water & Air Management…………………………………………………………….

5.6. Utilities – Water, Gas, Electricity & Infrastructure…………………………………….

5.7. Services, Connectivity & Retail………………………………………………………………….

5.8. Green Environment Resilience………………………………………………………………….

5.9. Governance………………………………………………………………………………………………

5.10. Food & Health…………………………………………………………………………………………..

6. Action Plan……………………………………………………………………………………………………………….

3

Executive Summary

A Smart Campus actively learns from and adapts to the needs of its people and place, unlocking the potential of e-technology and enabling world-changing learning and research methodologies. Also to create an environment friendly atmosphere enabled with technology is the main goal of a smart campus. It is a modern application in the standard of the internet of things. The idea of building a “smart campus” implies that the institution will adopt advanced ICTs to automatically monitor and control all the facilities on campus. The students and staff members will benefit from location-aware services for using campus equipments and collaboration services. This will add values for students and increases the attractiveness of the campus. New emerging technologies have changed human lifestyles dramatically. The smart campus implements an IoT-based system to a selected part of campus like the Campus Environment, Campus Security, Campus Parking, Campus Building, Campus offices, and classroom to create smart environment, smart security, smart building, smart parking, smart offices, and smart classrooms. Apart from focusing on technology, smart campuses are inevitable to restore environment and resources and help the student communities for a smart and sustainable future. There are more than 750 universities, 40,000 colleges and institutes, and 1.5 million schools in India where around 200 to 300 million students are engaged in learning. Apart from being a significant consumer of energy, water and other utility and material resources, the educational campuses provide captive young thinkers action-based education on sustainable development. They are the spaces bubbling with potential opportunities to create skilled and 'job-ready' professional force. Government of India has initiated a project on smart campuses throughout the country. The project is flagship activity of Technology, Education, Research and Rehabilitation for the Environment (TERRE) Policy Centre, a think-tank and action platform for sustainable development. It is called Smart Campus Cloud Network (SCCN). JSS group of institutions has several educational units at different regions and the trust has decided to implement the development of smart campus in all these institutes. Jagadguru Sri Shivarathreeswara Academy of Higher Education and Research (Deemed to be University) has planned to adapt for a smart campus as per the need of the hour. The institute is focusing on 10 key elements that comprise smart campus viz. 1. Buildings, 2. Education, Learning & Digitization, 3. Sports & Recreation, 4. Safety & Security, 5. Waste, Water, Air management, 6. Utilities – Water, Gas, Electricity & Infrastructure, 7. Services, Connectivity & Retail, 8. Green environment resilience, 9. Governance, 10. Food & Health. The institute is situated in a 43 acre land and comprises of Medical College, Dental College and University Departments (Faculty of Life Sciences and Health Systems Management Studies). As an initial step, the institute has surveyed the available facilities which would enable either to enhance or add smart features. Further, discussions and feedback from stake holders are in progress which would add significant values towards the goal. Students are the central part of the smart campus as they are the ambassadors of a sustainable future. To begin with, the institute has planned to focus on Swachhta Ranking, an initiative by the MHRD, Government of India which earmarks the potential of an institute to be smart.

4

In this process, the institute has reviewed all the existing amenities and also has narrowed down to focus on at least five key elements among the above mentioned 10 namely 1) Education, Learning & Digitalization 2) Waste, Water, Air management, 3) Utilities – Water, Gas, Electricity & Infrastructure 4) Green Environment resilience and 5) Food & Health. To kick start the action plan for “Smart Campus” project, the institute has planned to focus on one issue per key element in order to achieve the goals. Covering the key element 1) Education, Learning & Digitalization, as per the requirements of the NAAC, the institute is Wi-Fi enabled and facilitates accessibility for students & faculty. In order to provide skill based education, Medical College has proposed for a skill development lab for Rs. 5 crores and the project is planned to be executed in 3 phases. Covering the key elements 2) Waste, Water, Air Management and 3) Utilities – Water, Gas, Electricity & Infrastructure, we have identified space to install Biogas plant to manage kitchen waste and initial communications have been initiated with renowned vendors. GPS technologies & solutions and GG Enterprises have come forward for biogas installation (quotation is attached for reference). Sewage Treatment Plant (STP) and laboratory water treatment has been focused. A detailed budget of Rs. 1.6 Crore has been quoted by Microclean Private Ltd. to set up an STP. In order to manage water, electricity and infrastructure by installing sensor enabled water meters, smart switches for lights and fans; we have consulted with SHINFOTECH Pvt Ltd. An initial survey of the Medical Institution campus is under process. A complete survey of trees both in Medical College campus and Pharmacy College, Mysore has been achieved covering the key element of Green Environment Resilience. Kitchen automation is an area that needs more importance and the process has been initiated at the Boys Hostel in the Medical College Campus.

5

I. INTRODUCTION:

A smart campus is achieved by integrating sustainability to every component of an institute including building structures, renewable resources, digitalization through internet of things (IoT), bringing together the institute, stake holders, faculty and external members to understand the necessity of a sustainable and environment friendly campus. Jagadguru Sri Shivarathreeshwara Academy of Higher Education & Research, Mysuru has established its State of Art Campus using cutting edge technology. In order to achieve the smart campus status, the institute and the constituent colleges have initiated the process of implementing technologies like

1. Smart Physical Security and Surveillance

2. Smart Wi-Fi Enabled Campus

3. Smart Metering

4. Smart Recycling Process

5. Smart Transportation System

6. Smart Energy Conservation and Utilization practice

7. Smart Hostel Management

8. Smart Canteen/food court management

6

2. SMART CAMPUS POLICY

I. OBJECTIVE:

• To embed smart technology into daily life of the campus, providing an

opportunity for the development and application of innovation and technology

to support a smart campus.

• To integrate an enhanced process and programme focused on energy, materials,

security, health, transport and environment management.

• To focus on maintaining “Eco friendly institution” through best practice.

• To educate students on the importance of sustainability for a smart future

• To provide world class facilities to enable nationally and internationally

renowned industrial/institutional partners to co-locate on the campus.

II. SMART CAMPUS INITIATIVES:

a) Over all activities:

• The Institute implemented CCTV cameras for the security of students day and

night from the year 2010.

• The surveillance has built in analytic and intelligence for immediate remedial

measures.

• Students are always connected to smart Wi-Fi.

• Healthy environment to support the mental, physical and social well being of the

students and staff of the Institute.

• Daily power and water consumption data per student and room basis are

captured and analyzed for reducing consumption cost.

b) Students Centric Smart Campus:

• Students are ensured a safe and secure homely atmosphere and are being

monitored round the clock.

• Students have high speed internet both on campus and hostel rooms.

• Smart portal has a great impact on both students and stakeholders who are

directly involved in daily hostel operations.

• Students are involved in the making of smart campus through several mini and

major projects.

7

c) ICT Based Smart Campus:

• Physical security of students in the campus was a big challenge.

• 400 CCTV cameras are in operations for surveillance at all times.

• Internet plays a vital role in enabling students to pursue their academic goals.

Internet with adequate band width was provided to make the campus Wi-Fi

enabled.

• Optimization and improvement can only be brought about by identifying

consumption patterns. The goal was to reduce the consumption of water and

electricity to the lowest levels possible. Smart Metering was implemented for

taking optimal decisions.

• A large number of students join every year. University needed a SMART portal

where in all services are taken care centrally from student entry in hostel and to

their exit. Smart Portal was made operational for connectivity with students at

all times.

d) Environment Friendly Smart Campus:

• In order to minimize energy usage, improve the efficiency of all energy/

resources (natural resources, water, electricity) consuming systems and

equipment, and improve the environment in all facilities, Jagadguru Sri

Shivarathreeshwara Academy of Higher Education & Research has adopted an

energy / resources conservation and recycling policy.

• Conservation of energy and natural resources and recycling process is an integral

part of Jagadguru Sri Shivarathreeshwara Academy of Higher Education &

Research facilities’ design and usage.

• The University employs a variety of energy conservation, recycling, and other

techniques to lessen the consumption of resources and achieve the lowest

feasible life cycle costs.

• Energy conservation measures will be achieved by using the most cost-effective,

energy-efficient approach with consideration given for flexibility of use and future

remodeling convenience. Recycling efforts are encouraged at the

Institution/department level.

• All faculty, staff, students, design consultants, and construction contractors

observe energy and resource conservation measures employed by the campus.

• The Campus Facilities Maintenance & Management Authority- Deputy Registrar

shall be the principal coordinator of all design disciplines, which includes

responsibility for the implementation of this policy.

8

• Constituent Colleges & Departments are responsible for internal energy

conservation and recycling efforts.

• The Transport Policy provides the Institute with a standard procedure for the

acquisition, enhancement, use, control, maintenance, repair, checking fuel

efficiency and disposal of the Institute's vehicles and for the management of

related forms of transport engaged for Institute activities.

III. LONG TERM GOAL:

The long-term strategy of the University focuses on the creation of a world-changing,

connected, healthy and vibrant university campus. To achieve the goal, the Institute will

concentrate on:

a) Digital Environment

▪ Open, flexible, integrated, interoperable, secure and scalable ICT architecture; ▪ Sense, capture, monitor and evaluate data to support and study the performance of

the campus in real time.

b) Integrated Urban Energy Systems

▪ Low carbon, low impact energy in a complex urban environment, focusing on generation, storage, distribution and management.

c) Data-driven Infrastructure Innovation

▪ Resilient infrastructure systems ▪ Innovation in infrastructure design and delivery ▪ Building Information Modeling (BIM) for design and life-cycle performance.

d) Health & Wellbeing

▪ Evaluate, understand and improve the physical environment ▪ Develop new practices for workplace wellbeing ▪ Develop the technology, including wearable technology, to measure and influence

health related behavior.

e) Student Experience and Pedagogy

▪ Data-driven services and spaces for an improved student experience ▪ Technology-enabled learning & teaching (including active learning, interactive

teaching, flexible study).

9

IV. AUTHORITY:

The Vice-Chancellor & Registrar of JSSU hold delegated authority and are

responsible for all aspects of the Institute’s “SMART CAMPUS POLICY”.

The Smart Campus Policy of Jagadguru Sri Shivarathreeshwara Academy of Higher

Education & Research follows:

• The Swachh Bharat Mission (Urban) guidelines, Government of India.

• National conservation strategy and policy statement on environment and

development, Government of India.

• National Cyber Security Policy, Ministry of Communication and Information

Technology, Government of India.

10

3. LANDSCAPE OF JSS MEDICAL INSTITUTIONS CAMPUS

Fig.2. Topographical view of JSS Medical Institutions campus

JSS Medical Institutions campus is situated in a 43 acre land area and consists of Medical College, Dental College, Faculty of Life Sciences and hostels.

11

4. SMART CAMPUS – BEGINNING

For meaningful and successful sustainability programs in campus we need to

• Set clear strategies and goals

• Have a comprehensive approach

• Integrate students, faculty, staff and external partners

• Initiate pilot projects in several areas involving students

• Plan policies, financial resources, facilities management, curriculum, sustainability

literacy, ecosystems, land use, energy resources, etc.

Fig.1. Stake holders involved in the building of a smart campus with students occupying the central position

12

5. Key Elements of a Smart Campus

1. BUILDINGS

2. EDUCATION, LEARNING & DIGITISATION 3. SPORTS & RECREATION 4. SAFETY & SECURITY 5. WASTE, WATER, AIR MANAGEMENT 6. UTILITIES – WATER, GAS, ELECTRICITY & INFRASTRUCTURE 7. SERVICES, CONNECTIVITY & RETAIL 8. GREEN ENVIRONMENT RESILIENCE 9. GOVERNANCE 10. FOOD & HEALTH

Details of existing amenities and facilities required for a smart campus pertaining to each key element in general is given below

1. BUILDINGS

Buildings are the main criteria of functionability. The JSS Medical Institutions comprise JSS Medical College, JSS Dental College, Faculty of Life Sciences (Heritage Building), Hostels and Playground.

Existing Facilities in the campus 1. Well - equipped Auditoriums (MC – 600 and DCH – 150 capacity), 6 no’s of Gallery Halls,

Council Hall-01, Board Rooms – 03, Discussion Room – 5 no’s. with AC’s 2. Hostels (4 blocks boys hostel, 5 blocks girls hostel, 3 mess blocks) 3. Hostels (off Campus) @ HIG House Building, MIG House Buildings, Doctors Quarters,

Unnathinagar, Belavatha, PG Girls Hostel @ old JSS Hospital building. 4. Guest house 01 (R-38, SR-08, VIP S-02) 5. Staff Quarters (off campus) 6. Washrooms (Male / Female / Physically Challenged) 7. Drinking Water 8. AV Solutions 9. Asphalted Roads with connectivity to all the buildings 10. Drainage System 11. Solar Water Heaters 12. Elevators (JSSMC -2, JSSDC&H – 2, GH – 1 no., PG Hostel @ JSSH Premises – 1 no.) 13. Common Room for Boys and Girls (students) with washroom – 5 no’s.

Ladies Common Room for staff – 1 no.

13

2. EDUCATION, LEARNING & DIGITISATION

Digitization of teaching and study materials is under process. Accessibility to study materials by students is rendered through Wi-Fi connectivity in the entire campus. Most of the rooms are IT enabled in order to enhance learning through PowerPoints and videos. Spacious and well furnished libraries cater the needs of students in learning. Existing Facilities

- Smart class room – 2 no’s (MC & DCH) - Simulation lab (Pharmacology and Physiology) - Digital Library – 4 no’s (MC - 40 no’s. DCH – 15 no’s. HSMS – 5 no’s. FLS – 28 no’s) - Outreach programme facility(ISRO open Learning) - IT enabled classroom (with projectors) - Upton 1 GBPS uninterrupted internet services through NKN connectivity for a period

of 10 years is availed (presently, 300 mbps) - All the buildings are connected with OFC cable. - Wi-Fi connectivity is enabled (within the building) - MS Windows license version computers - JSSU online services (for all official communication)

Projects / Facilities in pipeline - Skill lab at an approximate cost of Rs. 5.00 crores is under process and planned to

implement it in 3 phases. Required Facilities:

- Access to international journals becomes vital in order to strengthen the knowledge on research components and also to be well informed about research activities throughout the world.

- Installation of smart boards and learning tools - Support entrepreneurship ideas among students - Development of Technology Incubation Center which can nurture startup ideas of

students as well as support local small scale entrepreneurs and farmers. 3. SPORTS & RECREATION

Health and well-being are an important aspect of academic success and retention; when a student is healthy in mind and body, they are better able to focus on and complete their studies. By taking measures to improve a student’s health and well-being, an institution is actually helping its self by potentially increasing the student’s GPA and graduation, and retention rates. The goal is to have the campus community flourish and be fulfilled individually and within our communities where we live, learn, work, and play. As one of the vital stakeholders in Health & Well-Being, the Sports and Campus Recreation Complex should fulfill this vision by providing space and opportunities for students to discover and affirm their own well-being

14

practices in five different dimensions (emotional, physical, social, professional and spiritual) that lead to a healthy lifestyle. Existing Facilities:

- The university hosts both indoor and outdoor stadiums for sports

- Sports committee is already functioning to identify the talented individuals and the

department supports.

Projects / Facilities in pipeline

- Upgradation of Basketball Court at an estimated cost of Rs. 50 lakhs is in the pipeline (proposal submitted for approval).

- Upgradation of the sports ground with gallery seating at an approximate cost of Rs. 2.00 crores.

Required Facilities: - An IoT enabled gym which provides a platform for a healthy stay. IoT can provide

information regarding the timing and at what time the students could find the gym

free for their use.

4. SAFETY & SECURITY Existing Facilities:

- The FLS campus is enabled with CCTV cameras for continuous monitoring. - Committee comprising of faculty against ragging and sexual harassment is highly functional

and therefore such circumstances are completely avoided in the campus. - An efficient committee for student counseling system has been constituted to further

address issues of students both academically and personally. The system is integrating students, teachers and parents.

- Hostel premises are equipped with cameras and continuous surveillance under security personnel. A regular check of food for nutrition and hygiene is carried out in order to provide safe health Required Facility/Knowledge:

- Laboratories are not equipped with fire/smoke sensors. Therefore installation of fire sensors is necessary.

- Regular workshops on safety management are required for both faculty and students to help them handle emergency situations.

- Interaction with Laboratory managers and electricians should be facilitated for the safety of the campus. Their contacts should be displayed and readily available in case of emergency.

- Security through Internet of Things is a modern technology that keeps us connected wherever we are. This helps in monitoring the labs and premises even from home during non-working days. IoT also enables strict security of encrypted data.

15

5. WASTE, WATER & AIR MANAGEMENT

Existing Facility: WASTE MANAGEMENT: - Bio-medical waste management service from M/s. Shree Consultants is being availed

since May 2003 (Dental & Medical). - Segregation and collection of dry and wet garbage. - Color coded dustbins are provided across the campus.

WATER MANAGEMENT: - Rain water harvesting tank and connectivity (30,000 ltrs (storage)) - Ground water and bore well recharge pits / points (10 No’s.) and Infiltration tank 01no.

(15,000 ltrs.) - Re use of RO rejected water for gardening purpose (10,000 ltrs. – one tank). - Water sprinklers are in place AIR MANAGEMENT:

- 2/3rd of the campus is covered with greenery Required Facility/Knowledge:

- Proper disposal facilities for degradable and non-degradable wastes need to be developed. Laboratory wastes containing toxic chemicals need to be disposed as per regulations. Eg. Ethidium bromide used for DNA staining is carcinogenic and hence need to be disposed as per standard protocols.

- An awareness camp is necessary to educate on segregating degradable & non-degradable wastes.

- All water pipes can be connected to a metric meter in order to have a data on daily water consumption.

- Identifying damaged pipes and sprinklers and replacing them with efficient ones can save water. Waste Water Management:

- Hostels, for instance are the main source of sewage water, while waste water from canteens, restaurants and campus buildings add up to the sewage. An effective sewage water treatment in a biological aspect can replace conventional chemical water treatment, as a need for sustainable green management is vital for a smart campus.

- Student Projects/Pilot Projects are a main source of ideas that can be implemented after successful completion of the projects.

16

Proposed projects to be initiated for bio waste management

- Solid bio waste from hostels and canteens can be utilized for biogas production. - Citrus fruit wastes from food courts are used to produce sanitizers which can replace

chemical sanitizers being used to clean floors and toilets. - A pilot project on production of sanitizers from bio waste is under progress. The project is

run by a 1st Year B.Sc., Biotechnology student. Proposal for Phytoremediation of Sewage Water

- One of the sustainable waste water management is through phytoremediation - Phytoremediation is defined as treatment of sewage water by employing plants in order to

recycle water for further usage. Although phytoremediated water is not fit for drinking, it can be used to increase ground water level or as a source of water for gardens and herbals in campus.

- While the treated water can be reused, the plants used for treatment can be used as raw materials for biogas production and biomanure production.

- Further, electricity can be produced from the biogas produced. - The project is planned for either a Master degree internship or a major project for B.Sc.,

students.

An outline of the proposed project for sewage water treatment is given below

17

6. UTILITIES – WATER, GAS, ELECTRICITY & INFRASTRUCTURE

Existing Amenities

- Well-furnished class rooms with AV solutions - Libraries – 4 no’s (MC, DCH, HSMS, FLS) with online journals and data bases - Transportation facilities - Bus – 9 no’s - Car / Jeep – 9 no’s. - Two wheeler – 1 no. - 24 x 7 electricity - 24 x7 water supply - Parking

A survey of water utility and storage in the Medical Institutions Campus is given below

BUILDINGS WATER CAPACITY

Main Over Head Tank 4,50,000 Ltr

Main Over Head Sump 2,00,000 Ltr

Over Head Tank Entrance 50,000 Ltr

Girls Hostel D Block Sump 85,000 Ltr

Girls Hostel D Block OHT 75,000 Ltr

Boys Hostel Sump 40,000 Ltr

MC Over Over Head Tank 30,000 Ltr

Guest House Sump 87,000 Ltr

Guest House OHT 25,000 Ltr

Canteen Sump 10,000 Ltr

Canteen OHT 10,000 Ltr

Total 10,62,000 Ltr

18

Requirements: Smart meters have become the top IoT device among utility companies in the last several years. These devices attach to buildings and connect to a smart energy grid, which allows institutions to more effectively manage energy flow into buildings.

- Smart meters connected with IoT - Leakage sensors to detect water, gas or electricity - Replace old and rusted pipelines - Manage complicated electricity lines - Sensor enabled lamps/fans to automatically switch on when a room is occupied or

off when it is empty - Vacuum/suction type of closets to avoid water wastage - Effective rain water harvesting system - Smart parking facilities to indicate availability of parking slots - Restricted movement of vehicles within campus – towards green environment - Pedestrian friendly atmosphere - Utilization of freely available space for green growth - Rain water harvesting facility

7. SERVICES, CONNECTIVITY & RETAIL

- Dental Hospital (366 dental chairs) - Dental Mobile Van (1 no. for community services) - Bank - Post Office - Pharmacy - Co-operative Society - Laundry / Cobbler - Telecommunication - Incinerators - Photo copiers and bindings - Health Insurance services(TATA AIG) - JSS University NSS Unit - Free Wi-Fi - Common communication social platform like a link that connects faculty, students

and the institute. - An in house pharmacy is functioning within the campus to cater the needs of

students as well as public. Requirements:

- Battery operated green vehicles for internal transport - IT services to distribute laptops to faculty - Creche facilities for kids of faculty

19

8. GREEN ENVIRONMENT RESILIENCE

- The FLS campus is beautifully maintained and gives importance to green environment by planting several plants in and out of the campus.

- The campus is continuously stressing on “No Plastics” - Dustbins have been distributed to segregate bio and paper wastes

Requirements:

- Support pilot projects from students to replace plastics as far as possible - Proper disposal of laboratory waste - An aquatic ecosystem is proposed. Support for the same is required.

9. GOVERNANCE Existing Facilities:

- Periodical seminars & conferences, - Faculty development programme - Hands on training - Skill development programs (computer, Tally, Simulation, Software, Access to data

bases) - JSSU Online Platform - Computers / Laptops / Printers / Scanners / Photocopier’s / Projectors etc., are

provided based on requirement to the administrative & supportive staff and for the Depts., as required. Requirements:

- Implementation of orientation programs for newly joined faculty and students - Organizing seminars on work ethics - Staff Support System - Counseling system to handle disputes among employees

10. FOOD & HEALTH

JSS Institute hostels are well known for its aesthetic food and hygiene. The

Institute follows strict vegetarian food both in hostels and food court. A regular

check on food and hygiene is carried out to ensure safe health of the students.

Existing Facilities:

- Food Court (80 seating capacity) - Coffee vending machine - JSS Health Center - Mess / Kitchen ( 3+1 +1 Nos) - Staff Dining Hall – 2 no’s. (JSSU) - Dining Halls @ Hostels, Guest House, Food Court (5 no’s.)

20

Requirements:

- Pilot projects on food storage and preservation - Educate the students and faculty on importance of Phytonutrients in food - Pilot studies on roof gardening, hydroponics, aquaponics and aeroponics for

sustainable green farming - Educate students on organic farming and reduction of carbon foot print - Regular health check up for students and faculty - IoT in maintaining health records - Support Extension activities to educate down trodden communities regarding food

habits and health benefits - Pilot projects on identifying active components from herbs against diseases - Frequent seminars and workshops on food and health - Counseling system to improve health status - Incorporating Yoga for physical and mental well being.

21

ACTION PLAN After identifying the existing amenities and required facilities, working in phases would be the best approach to attain a Smart Campus status. CLEAN CAMPUS FOR A SMART CAMPUS On September 14th Ministry of Human Resource Development (MHRD), Government of India released a Press Report on ‘SWACHHTA’ Ranking for the year 2017. An award ceremony based on ‘SWACHHTA’ Ranking 2017 of Higher Educational Institutions was held in New Delhi today. Union Human Resource Development Minister, Shri Prakash Javadekar gave away the prizes to the awardees. Speaking on the occasion, the Minister said that the Swachh Bharat Abhiyan is the most significant cleanliness campaign by the Government of India. The Minister said the students are cleanliness ambassadors and along with the support of people and institutions they will lead the vision of Clean India of our Prime Minister Shri Narendra Modi. He also said to make Higher Educational Institutions a smart campus we should focus on cleanliness as well as waste management.

The minister quoted ‘Save water, save electricity, promote cleanliness and manage waste to become smart campuses’.

An exercise to rank Higher Educational Institutions (HEIs) on the basis of cleanliness and hygiene has been undertaken and concluded.

Parameters for a clean campus were

➢ Student/toilet ratio

➢ Kitchen hygiene,

➢ Availability of running water,

➢ Modernity of toilet & kitchen equipment,

➢ Campus green cover, garbage disposal in hostels and academic buildings,

➢ Disposal techniques,

➢ Water supply systems

A certain weightage to whether the institution has adopted any neighbouring locality or village to spread awareness & activities in Swachhta was also considered.

22

KEY ELEMENTS TO BE FOCUSED IN PHASE 1 Though every element is equally important, we have identified and distributed the elements to work on phases. According to the plan, the following are the key elements to be focused during phase 1

1. Education, Learning & Digitization

2. Waste, Water & Air Management

3. Utilities – Water, Gas, Electricity & Infrastructure

4. Green Environment Resilience

5. Food & Health

EDUCATION, LEARNING & DIGITIZATION

➢ INTEGRATION OF SUSTAINABILITY ACROSS CURRICULUM ➢ INTEGRATION OF RESEARCH, TEACHING & OUTREACH ➢ EDUCATE STUDENTS ON SUSTAINABILITY (ASSIGNMENTS IN THE FORM OF

ACTIVITIES AND EFFECTIVE DISCUSSION ON TOPICS RELATED TO SUSTAINABILITY) ➢ SUPPORT INTER-DISCIPLINARY RESEARCH ➢ RECRUITMENT OF INTERNATIONAL GUEST RESEARCHERS

A first round of meeting was held among the faculty members in Faculty of Life Sciences to discuss the ideas of integrating research and educate students on sustainability. Faculty of Life Sciences identified a Resource person to discuss further on sustainability. Dr. Saikumar who currently is a Project Leader working for the Berlin Social Science Center (WZB, Germany), with the project office at Bidadi, Ramanagara District was invited for an interactive session.

23

Fig.4: Interactive session with Dr. Saikumar on the 1st meeting held on 20th December 2017 on sustainability.

Some students have come forward to initiate their projects of interest in order to develop entrepreneurship. Projects initiated:

1. Production of medicinal wine 2. Cultivation of mushrooms 3. Production of bio sanitizers to replace chemicals to clean the floors and toilets 4. Aquaponics

The idea behind the initiation of such projects is not only to develop entrepreneurship but also to reach the neighboring rural areas to extend the ideas to Self Help Groups to understand the concept of sustainability.

Fig. 5: Students involved in the production of medicinal wine and cultivation of mushroom.

24

Lecture/Seminar Hall at Faculty of Life Sciences

Proposal

The existing library facility is being moved to the Heritage Building. The total carpet area of

the old library is 800 Sq. Ft. with a dimension of 20x40.

The room can hold 100 chairs with foldable writing pads.

25

Facilities Required:

1. A movable stage to be constructed and fixed

2. White board

3. LCD projector with a screen of size 10x8

4. Podium with mike & collar phone

5. Speakers

6. Computer desk with chair

7. Air Cooler (2 Nos.)

8. Students Chair with foldable writing pads.

26

Centralized Research Lab Facility Proposal

Department of Water & Health, Faculty of Life Sciences, JSS University consists of 4 wet labs

(1 UG lab, 1 PG lab, 1 Environmental Science lab& 1 Food Science lab) and 2 dry labs

(Bioinformatics lab & Geoinformatics lab). Wet labs are being used to conduct practical

courses for both Undergraduate and Postgraduate students. Apart from UG & PG courses,

research scholars are also continuously engaged in research activities.

The Department is swiftly growing and the number of students has remarkably increased

compared to the past which means the available laboratory space is insufficient to fulfill the

practical courses and research activities in the same lab space. In order to provide a better

research ambience and space for the faculty, students and research scholars, we would like

to propose for a centralized bioresearch laboratory which could enhance research activities

considerably. Currently, FLS hosts Govt. funded projects worth over 1 crore and equipments

are being purchased both from funded projects and FLS annual budget.

In this connection, the existing office space could be converted to the centralized research

lab as shown in the figure below.

Fig.1: Plan of the proposed centralized research laboratory at FLS

Components of the proposed Centralized Bioresearch Lab

1. Bioinstrumentation Lab

This lab would host all the general instruments such as Digital colorimeter, UV-Vis

Spectrophotometer, Light microscopes, ELISA Reader, Tabletop Centrifuges, High

27

sensitivity Weighing Balance, pH Meter, Probe Sonicator, Fluorescent Microscope

etc. The Lab needs running table top on 3 sides with chairs.

2. Animal Tissue Culture Lab

Most of the research pertaining to Biochemistry, Biotechnology, Molecular Biology,

Immunology and Microbiology need a well established Animal Tissue Culture facility

to test compounds of interest, to study cell morphology or developmental dynamics

of cells, etc. The facility needs a laminar flow hood, inverted microscope, a

refrigerator and a CO2 incubator. The facility needs roof ceiling with Air

Conditioning. Room entry needs over head air flow.

3. Molecular Biology

The molecular Biology lab would be an important lab that follows the results of

animal tissue culture. The existing room needs to be bifurcated to provide restricted

entry to the molecular biology lab. The facility would host thermo cycler (PCR), Gel

Electrophoresis Units and Gel Documentation. The lab needs to be isolated from the

other facilities to reduce contamination of RNA and DNA.

4. Histology Lab

This lab would facilitate the studies on cells and tissues for expression patterns of

proteins following cryosectioning of cells or tissues. The lab will host cryostat,

refrigerators for storing sections and reagents, light microscopes etc.

The centralized research facility would not only enhance our quality but also might

increase the opportunities of obtaining more projects from various funding agencies.

Further, the facility can also considerably help gaining points for NAAC, NIRF, ISO and

other similar National agencies.

Facilities Required

1. Granite table tops fixed on iron legs for all the proposed labs as prescribed

2. Air Conditioning for Bioinstrumentation and Animal Tissue Culture labs

3. Room partitioning in the Chairman’s cabin for Molecular Biology & Histology Lab

4. Plug points to ensure proper running of -80°C Freezer and other high end

equipments which need higher power supply

28

WASTE, WATER & AIR MANAGEMENT UTILITIES – WATER, GAS, ELECTRICITY & INFRASTRUCTURE An initial survey was carried out, especially in the hostels for waste disposal. Dustbins with color codes are already in place.

We have interacted with the hostel officials, care takers and cooks regarding the food wastage and management. Approximately 100 Kg is being generated in the form of kitchen waste, vegetable waste and thrown away remains of food. Apart from this waste, almost 150 liters of starch water from cooked rice is being disposed. The waste is enough to install a biogas unit at the backyard of the hostel premises.

29

Though pilot projects could be initiated for students for biogas production, the necessity of a fully functional biogas unit has become inevitable. One such unit (NISARGRUNA) was developed by Nuclear Agriculture and Biotechnology Division, BARC, Mumbai. The unit has won Padma Shri Award in the year 2013. The model biogas plant constructed at BARC is shown below for reference.

NISARGRUNA Biogas Plant and its advantages

The technology of Nisargruna Biogas Plant has been successfully transferred to several Government organizations and private sectors. We have planned to communicate after discussion with the institutional authorities.

30

Technical Details & Quotations for Biogas Plant

GPS Technologies

31

32

33

34

35

Item Offer

BioUrja – 500 KPD

Rs. 28,88,000/- plus GST@5% Installation & Commissioning – 90,000/- plus GST@5% Quarterly Fee for GPS Services Suite – Rs. 22,500/- plus tax

BioUrja – 200 KPD

Rs. 13,31,600 plus GST@5% Installation & Commissioning – 30,000/- plus GST@5% Quarterly Fee for GPS Services Suite – Rs. 18,000/- plus tax

36

Quotation for Biogas plant – GG Enterprises

37

38

INTRODUCTION Green connect resource management solutions along with their associates, M/S GG Enterprises, specializes in bio-energy generation from all organic biodegradable waste on turnkey basis including design, execution, installation, operation and maintenance. Green Connect uses a proprietary biomethanation technology – Uniformly Distributed Organic Waste Reactor (UDOW) for the effective treatment of organic waste containing high percentage of suspended solids. We have an installation base of more than 200 biogas plant across India. Our Vision is to see that zero waste is generated from every home/institution and everything got from nature is repaid! We have expertise in engineering, procurement, construction, operation and maintenance of bio-methanation plants ranging from 5 kg to 5000 kg per day capacity. With an expertise of over 7 years in the field of waste management, we have installed our bio-methanation plants in many corporate like Ramco Cements, KH Exports, Robert Bosch, Lucas TVS, Brakes India, Yazaki Wiring solutions, Kirloskar, India Cements etc. We also have Ready-to-Install, factory assembled Plug and Play model portable biogas plants of capacity of 5 kg upto 1000 kg per day. UNIQUE ADVANTAGES OF THE PLANT

➢ Indigenously developed with in-house R & D over the years. Proven Product with

multiple commercial units across India. ➢ Our Plant does not require large quantity of fresh water for operations. ➢ Fully automatic plant with manual intervention required only for feeding ➢ No need to remove the sludge. ➢ Our Pre-assembled plants are ready to use - Plug and Play model. ➢ Does not require any major civil work to install the plant and our plant can be

relocated very easily if required. (portable) ➢ Higher gas generation using proprietary UDOW technology ➢ No foul smell and does not attract birds and insects. ➢ Easy maintenance and can be operated by a single person. ➢ Our plant helps in reducing Green House Gases. ➢ Advanced plant health monitoring system using app. ➢ Depreciation benefit available -80% under Income tax Act in the year of installation

of biogas plant.

39

SALIENT FEATURES OF THE PROPOSED RENEWABLE ENERGY- INTEGRATED BIOGAS PLANT @ JSS MEDICAL COLLEGE –MYSURU Treatment Capacity Upto 500 kg/day of food and vegetable waste.

Biogas Produced Approx. 75 cubic meters of biogas/day which is

Equivalent to 35 kg LPG/Day. Organic Manure Generated

Approx. 3 ton/ month (This can be used for Gardening as well as it can be sold commercially)

Water Required Approx. 500 litres / day Space required Approx 850 sq ft ( Portable model) Manpower Only 1 operator required for waste loading, general maintenance

and cleanliness for 2-3 hours in a day.

Power supply EB incoming power supply with earth (10KW).POWER

CONSUMPTION OF 8 UNITS/DAY.

Note: 1) The biogas generation is proportional to the quantity & quality of input waste loaded into the system. 2) Environmental impact cannot be quantified in terms of money. 3) Saving in space from conventional biogas plants cannot be quantified. 4) Savings in cost of disposal of waste at its source of generation cannot be quantified in terms of money. 5) Overflow from Solid-Liquid separator to be connected to STP/ETP.

THE PROCESS The basic concept of our design is based on a process known as Anaerobic Digestion (AD) and specifically modified by GREEN CONNECT®, for the waste containing high percentage of suspended solids. The segregated organic food waste will be brought to the plant site. It will further be crushed through crusher along with suitable quantity of water to form slurry. This slurry will be fed into the Inlet chamber. The slurry will be mixed properly and then pumped to the GREEN CONNECT® Anaerobic digester. In the GREEN CONNECT® digester, the organic food waste is converted into Biogas and Bio-slurry. This slurry will be recycled using S-L separator in which the solid and liquid will be separated and the solid manure will be converted to manure cakes which is good organic manure and soil conditioner. The liquid manure will be partly recycled and the rest will be discharged suitably. There is no periodic removal of organic manure from the digester. The Biogas generated from the anaerobic digester will be collected in membrane balloon and suitably pressurized. The pressurized biogas will then be used for cooking applications. If the gas is not used, it would be necessary to burnout the same as the Authorities do not permit letting it out into the atmosphere. Thus, this process will be based on a “Decentralized Zero Garbage” concept.

40

TYPICAL FLOW CHART FOR GREEN CONNECT® RENEWABLE ENERGY DEVICE (BIOGAS PLANT)

LIST OF MACHINERIES & EQUIPMENT PROPOSED

FEED PREPARATION SECTION Food waste Crusher Waste collection tank Feed Pump Portable pH device ANAEROBIC DIGESTION SECTION Green Connect® Anaerobic Digester Green Connect® Anaerobic Digester Internal Proprietary Modules BIOGAS STORAGE Biogas Balloon along with enclosure on top of the digester Biogas booster pump Pressure Switch & Gauge H2S removal gas tank

41

Moisture Traps Biogas stove Biogas flowmeter Flame Arrestor OTHER MISCELLANEOUS ITEMS Control Panel Electrical Works Piping Works Tool Box with tool kit Thermometer PRICE: INR 12,85,000 PRICE : Rs Twelve Lakhs eighty five thousand only

SCOPE OF EXCLUSIONS 1. Civil Works and pedestal for placing biogas plant. 2. Water inlet pipe to food waste crusher, processed waste final discharge pipe line. 3. Electrical Cabling will be laid from our panel board and if the panel board is above 5m from the proposed plant it will cost extra. 4. Power, Water and Lighting arrangements and generators if required during erection work. 5. Traveling, Lodging and Boarding arrangements for our team/engineers for supervision during erection and commissioning of plant. 6. Incoming Power Supply to our proposed panel board with 3phase connection, 415V, 75Hz with Single Phase Preventer. 7. Materials will be delivered immediately after inspection from our factory, Separate Room to store the materials, Security for the store room. 8. During Commissioning we will depute our Engineer for the same and we require an Operator to operate the plant. 9. Any other things which is not mentioned apart from our proposal. 10. Taxes extra as applicable at the time of erection/supply over the prices quoted above. 11. Prices will be Ex- factory works, Salem. Transportation extra. PERIOD OF EXECUTION OF THE PROJECT Fabrication/Construction of the biogas plant - 30-35 working days. Piping connections - 3 working days. Total estimated time required- 40-45 days Payment terms:- Stage 1- 80% advance along with work order. Stage 2- 20% on the date of installation.

42

AWARDS AND RECOGNITION “The Best Upcoming Entrepreneur 2014” By ICTACT-Tamil Nadu Delegate Speaker In “Green Summit 2014”, Banglore. Won 2nd Place In Aarambam Startup Contest By Nativelead Foundation -2014 Won “The Best Startup Company In Energy Sector” In Startupreneurs Conducted By CII-2014. One among “The Ten Most Interesting Startups” By The Times Of India. Recoganized by the NITI Aayog and ATW (Atal Innovation Mission) CONTACT DETAILS- Technical Mr.CHYTHENYEN.N.K 8124645694/9600329935 290/1B , SANIYASIGUNDU BY PASS, SALEM 636 015 Web- www.greenconnect.in Mail- chythenyen@greenconnect.in CONTACT DETAILS- Commercial N.TAMILMANIAN 9445744359/9840311359 ggenterpriseschennai@gmail.com Web - www.energycleanic.com Note - PO and all commercials - in the name of GG Enterprises-Chennai

43

Quotation for Sewage Treatment Plant JSSM/PAT/GG/STP/OFF/2011/375KLD February 21, 2018 To JSS University Medical Institutions Campus, Mysuru Kind Attn: To Dr. Gopenath, Dept of Life Sciences Dear Sir, Sub: Proposal for Supply of Sewage Treatment Plant Using Fluidized Bed BioReactors (FBBR) with a Treatment Capacity of 375 KLD to be installed at JSS University Medical Institutions Campus This is with reference to your enquiry; we are pleased to enclose our Techno- Commercial proposal for Design, Supply, Erection and Commissioning of the above mentioned with respect to subject work. We trust that you will find our proposal acceptable and we look forward to the receipt of your order at the earliest. For any Clarifications, Technical / Commercial discussion we shall be pleased to call on you, on hearing from you. Thanking you, Yours Truly, For GG Enterprises N. Tamil Manian 9445744359/ 9840311359 Enclosures:- Proposal for Sewage Treatment Plant - 3,75,000 Liters / Day. DESIGN BASIS The Sewage Treatment Plant is designed for a Capacity of treating 3,75,000 Liters/Day @ 19 m³/Hr. Raw Sewage Characteristics taken for design basis:- S.No Description of the Parameter Value 1 Ph 6.5-7.5 2 BOD (Biological Oxygen Demand) 300mg/lit 3 COD (Chemical Oxygen Demand) 900mg/lit 4 TSS (Total Suspended Solids) 150mg/lit 5 Oil & Grease 50mg/lit Treated Sewage Characteristics:- S.No Description of the Parameter Value 1 Ph 6.5-7.5 2 BOD (Biological Oxygen Demand) ≤20mg/lit 3 COD (Chemical Oxygen Demand) ≤100mg/lit 4 TSS (Total Suspended Solids) ≤20mg/lit

44

5 Oil & Grease Traces TREATMENT SCHEME FOR PROPOSED PLANT Primary Treatment:- Screening:-Large Debris entering in to the system will be protected with a screen installed before the Collection Sump. Collection Sump: - The Sewage Water collected from the Screen Chamber is let out in to the collection sump and it is aerated for even mixing of the Sewage Water. Secondary Treatment:- Fluidized Bed Bio Reactors: - The Fluidized Bed Bio Reactor is filled with high quality self supporting cylindrical shaped Poly Propylene Material. Bacterial Growth shall be generated by providing compressed air in Bio-Reactor (FBBR) and get attached to the PP media to form fixed film. Here the BOD, COD, Organic Pollutants get digested easily. Clarifier: - Here the treated water and Sludge will get separated. Tertiary Treatment:- Disinfection: - Hypo is dosed before filtration for disinfectant. Pressure Sand Filter: - It is used as final polishing unit for the removal of suspended solids. Activated Carbon Filter: - It is used as final polishing unit for the removal colour & odour. Treated Water Tank (Optional):- The filtrate water from Pressure Sand Filter and Activated Carbon Filter is collected in the treated water tank.

PROCESS DESCRIPTION:- 1. Primary Treatment:- Screen Chamber:- The waste water enters in to the Screen Chamber by gravity flow where Screen is fixed to remove the large debris entering into the Collection Sump. Collection Sump:- The Screen Chamber outlet is collected in the Collection Sump, from where the Sewage is aerated for even mixing and it is pumped to FBBR tank. 2. Secondary Treatment:- Fluidized Bed Bio-Reactor:- The sewage from the collection sump is pumped to the FBBR. The Fluidized Bed Bio Reactors are provided with ‘State-of-the-Art’ diffused aeration system. In the aeration process oxygen transferred takes place by molecular diffusion through the surface film between air and liquid and increases in proportion to the interface area for a given flow, the surface area increases and the rise velocity of the bubbles decreases with number of bubbles. This factor contributes to the higher oxygen transfer capacity of diffused aeration system. The Fluidized Bed Bio Reactors is filled with high quality self supporting cylindrical shaped made of Poly Propylene. Bacterial growth shall be generated by providing

45

compressed air in Bio-Reactors (FBBR) and get attached to the PP media to form fixed film which reduces BOD, COD & Organic Pollutants. Clarifier:- The treated water from the FBBR tank flows into the Clarifier, where Baffle well is provided to reduce the force of the waste water to allow it settle down, where the solids gets settled at the bottom of the tank and the clear supernatant water overflows into the clarified water tank. The settled sludge is transferred from Clarifier to Sludge Drying Beds for separating the sludge and water, and this water is transferred to Collection Sump and solid sludge can be used as manure. Clarified Water Tank:- The overflow water from the Clarifier is collected in the Clarified Water Tank. 3. Tertiary Treatment:- Pressure Sand Filter:- The pressure vessel in MSEP consumption with graded filter media supported on layers consists of pebbles and sand. The filtration media is chosen from carefully cleaned, sieved and graded filter sand. This Pressure Sand Filter is installed to remove the suspended solids present in it. Activated Carbon Filter:- The Pressure Vessel in MSEP consumption with graded filter media supported on layers consists of pebbles, sand and activated carbon. The filtration media is chosen from carefully cleaned, sieved and graded filter sand. A mixture of coarse, fine sand and activated carbon in predetermined proportion facilitates in depth filtration. In-depth filtration provides longer runs between backwashes and better quality of filtrate compared to surface filtration. Treated Water Tank (Optional):- The filtrate water from Pressure Sand Filter and Activated Carbon Filter is collected in the treated water tank. PROCESS DESIGN DETAILS:- Screen Chamber:- Normal flow designed: 19m3/hr No. of Screen Chamber: One Angle of Inclination: 450 Width of the Opening: 12mm Size of the screen chamber: 1.5m X 1.5m x 1.3m T.D Free Board: 300mm MOC of screen chamber: RCC with Epoxy Coating Collection Sump:- Normal Flow Designed: 19m3/hr No of Sump: One Retention Time: 10hrs Volume of the Sump: 190 m3 Size of the Sump: 8.0m X 8.0m X 3.3m T.D Free Board: 300mm MOC of Collection Sump: RCC with Epoxy Coating Fluidized Bed Bio Reactors:- Type: Attached Growth System

46

Normal flow designed: 19m3/hr No. of Tanks: Two Hydraulic Retention Time: 10 hrs Volume of the Tanks: 190 m3 Size of the FBBR - I: 5.7m X 5.7m X 3.3m T.D Size of the FBBR - II: 5.7m X 5.7m X 3.5m T.D Free Board: 500mm MOC of FBBR: RCC with Epoxy Coating Inlet BOD to the Reactor: 300mg/lit BOD Loading: 106Kgs/Day Clarifier:- Normal Flow Designed: 19m3/hr Supernatant Overflow: 19m3/hr No of Tanks: One Hydraulic Retention Time: 6 hrs Volume of the Tank: 114 m3 Size Of the tank: 6.2m X 6.2m X 3.3m T.D Free Board: 500mm MOC of Clarifier: RCC with Epoxy Coating SWD: 3.0m +0.5m Clarified Water Tank:- Normal Flow Designed: 19m3/hr No of Tanks: One Retention Time: 6hrs Volume of the Tank: 114 m3 Size of the tank: 6.2 m X 6.2m X 3.3m T.D Free Board: 500mm MOC of Clarified Water Tank: RCC with Epoxy Coating Sludge Holding Tank:- Normal Flow Designed: 19m3/hr No of Tanks: One Retention Time: 3 hrs Volume of the Tank: 57 m3 Size of the tank: 4.5 m X 4.5m X 3.5m T.D Free Board: 500mm MOC of Clarified Water Tank: RCC with Epoxy Coating Treated Water Tank (Optional):- Normal Flow Designed: 19m3/hr No of Tanks: One Retention Time: 10 hrs Volume of the Tank: 190 m3 Size of the tank: 8.0m X 8.0m X 3.3m T.D Free Board: 300mm MOC of Clarified Water Tank: RCC with Epoxy Coating

47

OUR SCOPE OF WORK & SPECIFICATIONS FOR SUPPLYING EQUIPMENTS:- 1. Screen Description Quantity 1 No MOC SS Screen with 12mm Spacing.

2. Raw Sewage Transfer Pumps DESCRIPTION Quantity 2Nos(1W+1S) Flow 19m3/hr Head 10m Motor 5HP MOC CI Type Submersible Make Kirloskar/Equivalent 3. Air Blowers DESCRIPTION Quantity 2Nos(1W+1S) Capacity 500 m3/Hr Head 5MWC Make Kay International/Equivalent

Motor 20HP Motor Make Kirloskar/Equivalent 4. FBBR Media DESCRIPTION Type Self Supported, Cylindrical Shape

MOC PP Quantity 1Lot Color Black Maximum Continuous Operating Temperature 800C

Specific gravity 0.90-0.95 Kg/m3 Media Usage FBB Reactors 5. Mechanical Arrangement for FBBR DESCRIPTION Quantity 1Set MOC MS with Epoxy Coating

48

6. Mechanical Arrangement for Clarifier DESCRIPTION Quantity 1Set MOC MSEP 7. Sludge Transfer Pump DESCRIPTION Quantity 2No’s Flow 19 m³/hr Head 10m Motor 5HP MOC CI Make Kirloskar/Equivalent 8. Filter Feed Pump DESCRIPTION Quantity 2 Nos(1W+1S) Flow 19m³/hr Head 35m Motor 7.5 HP MOC CI Make Kirloskar/Equivalent 9. Screw Pump DESCRIPTION Quantity 2 Nos (1W+1S) Capacity 3 m3/hr Head 20m MOC CI Type Monobloc Make Elgi/Equivalent 10. Filter press DESCRIPTION Quantity 1 no Capacity 15 plates MOC Ms & pp Type Vertical Make Cleartek/Equivalent 11. Pressure Sand Filter DESCRIPTION Quantity 1 No Diameter 1500mm

49

Height 2100mm Normal Flow 21m3/hr Filtering Media Graded Pebbles / Sand/activated carbon M.O.C MSEP Minimum Pressure 2.0Kg/cm2 Maximum Pressure 3.5Kg/cm2 Bursting Pressure 10Kg/cm2 Valve Butterfly Pipe Line 65mm Type Vertical 12. Activated Carbon Filter DESCRIPTION Quantity 1 No.

Diameter 1500mm

Height 2000mm Normal Flow 22m3/hr Filtering Media Graded Pebbles / Silex/activated carbon M.O.C MSEP Minimum Pressure 2.0Kg/cm2 Maximum Pressure 3.5Kg/cm2 Bursting Pressure 10Kg/cm2 Valve Butterfly Pipe Line 65mm Type Vertical

13. UV System DESCRIPTION Quantity 1No No. of Lamps 5No Capacity 0-20000 LPH Power Single phase Lamp make Philips/Equivalent

14. Piping DESCRIPTION Interconnected Pipes, Fittings 1 Lot

Make Supreme/ Prince /Equivalent

MOC UPVC/MS 15. Electrical Works DESCRIPTION Quantity 1 No Make L & T

50

Electrical Panel will be supplied for the above mentioned Mechanical Equipments.

ELECTRICAL LOAD DETAILS:- S.No Description Operating

Load KW

Total Load KW

Quantity Running Hrs

Total KWH/Day

1 Raw Sewage Pump

3.75 7.5 2Nos 20.0 75.00

2 Air Blower with Motor 15.0 30 2Nos 24.0 360.00

3 Sludge Transfer Pump 2.2 3.0 2Nos 4.0 6.0

4 Filter Feed Pump 5.6 11.2 2Nos 20.0 112.00

5 UV System 0.4 0.04 1No 20.0 8.0 6 Screw Pump 1.5 3.0 2 No 2.0 3.0 Total Load 564.0 80% of Total Load 338.4

COMMERCIAL OFFER Pricing for Supply of Materials: - S.No. Description Amount

(Rs.) 1. The Price for Supply of Sewage

Treatment Plant with a Treatment Capacity of 3,75,000 liters/day using FBBR Process.

23,05,000.00

Total Project Cost(Inclusive of Tax) 23,05,000.00 (Rupees Twenty Three Lakhs Five Thousand Only)

Payment Terms for Supply of Materials:- 50% of the total project cost as mobilization advance along with your work order 40% of the total project cost to supply of materials against proforma invoice 5% of the total project cost against erection 5% of the total project cost against commissioning Note-1: We request you to give the separate work order for Supply and Erection, Commissioning as mentioned above. Note-2: Order to be placed as per the description mentioned above. Terms and Conditions:- Delivery: 6- 8 Weeks from the date of work order along with Advance Payment. GST: 18 % Extra in the above price.

51

Erection & Comm: Included in the above price. Freight: Included in the above price. Validity: 15 days. Warranty:- 12 months from the date of Erection or 18 months from the date of supply whichever is earlier. This warranty includes only inherent manufacturing defects; it does not cover any replacement for normal wear and tear. SCOPE OF EXCLUSIONS 1. Water required for Erection and Commissioning to be supplied at free of cost. 2. Civil Works, Plant Room & Shed. 3. Raw Sewage inlet pipe to Screen Chamber, Interconnecting Pipes in the Tanks and Treated water final discharge pipe line. 4. Air vents line for all the treatment tanks, Treated water Pump. 5. Electrical Cabling will be laid from our panel board and if the panel board is above 5m from the proposed plant it will cost extra. 6. Lighting arrangements and generators if required during erection work, Ladder, handrails and walkway arrangement for tanks. 7. Incoming Power Supply to our proposed panel board with 3phase connection, 415V, 50Hz with Single Phase Preventer. 8. Materials will be delivered immediately after inspection from our factory, Separate Room to store the materials, Security for the store room. 9. For unloading the materials, equipments, tools, except ground floor will be your scope, Crane for lifting the materials. 10. During Commissioning we will depute our Engineer for the same and we require an Operator to operate the plant. 11. Any other things which is not mentioned apart from our proposal.

52

GG Enterprises-Chennai

JSS Medical University- Mysuru-STP Requirements and Proposals

Site Address Place

STP Req In

Lts

Proposed

Value in

INR

JSS University Medical Institutions Campus Mysuru 325 KLD 23,05,000

JSS University Medical and Dental College Hostel Mysuru 225 KLD 20,46,000

JSS College of Pharmacy Mysuru 125 KLD 13,85,000

JSS College of Pharmacy Ooty 100 KLD 10,98,600

GST-Taxes as applicable and other terms and conditions as per the proposal

53

VERMICOMPOSTING

Proposal for Vermicompost unit Vermicomposting is the use of earthworms and microorganisms to accelerate the composting process. Worms, through digestion, liberate plant nutrients from organic material converting it to rich humus. Worms consume up to their own weight daily, excreting castings which contain from five to eleven times the amount of plant available nutrients in the material consumed. Worms have been recognized to play a very important role in the enhancement and maintenance of soil penetrability, redistribution of nutrients, water flow and gas exchange. The pedogenic value of worms, in addition to the release of nutrients, has vast applications in agriculture and soil reclamation. The vigorous ability of worms to convert organic residue into a nutrient rich growth medium also has applications in waste management. Need for a Vermicompost unit within the campus

Our Institute maintains a very good green carpet area making the campus a green environment. With several trees within the campus, accumulation of fallen leaves and other plant materials account to around 50 – 100 Kg of bio-waste which is being dumped and finally removed by external agencies. With the smart campus initiative gearing up, it is worthwhile to consider our own strategies to handle the waste generated within the campus. In this connection a vermicompost unit would come handy to handle the plant waste materials which not only will help us manage waste but also serves as a student centered project to produce bio-manure.

54

Process

The processes of composting crop residues / agricultural wastes using earthworms comprise spreading the agricultural wastes and cow dung in gradually built up shallow layers. The pits are kept shallow to avoid heat built-up that could kill earthworms. To enable earthworms to transform the material relatively faster, a temperature of around 30° C is maintained. The final product generated by this process is called vermicompost which essentially consist of the casts made by earthworms eating the raw organic materials. The process consists of constructing brick lined beds generally of 0.9 to 1.5 m width and 0.25 to 0.3 m height inside a shed open from all sides for a small scale unit. For commercial production, the beds can be prepared with 15 m length, 1.5 m width and 0.6 m height spread equally below and above the ground. While the length of the beds can be made as per convenience, the width and height cannot be increased as an increased width affects the ease of operation and an increased height on conversion rate due to heat built up. Cow dung and farm waste can be placed in layers to make a heap of about 0.6 to 0.9 m height. Earthworms are introduced in between the layers @ 350 worms per m3 of bed volume that weighs nearly 1 Kg. The beds are maintained at about 40- 50% moisture content and a temperature of 20–30°C by sprinkling water over the beds.

55

Design of a Vermicompost Unit

Construction Unit and Budget

4 Compartments (Length 20 Ft X Breadth 5 Ft X Height 4 Ft each) Shelter with roof top

56

UTILITIES – WATER, GAS, ELECTRICITY

SHINFO Technologies, Pvt. Ltd.

SHINFO Technologies private limited was founded and promoted by young technocrats

heading the forefront of new technologies and new innovations in the industry. The

company is fully owned by Indian residents having its headquarters in Bangalore, India. We

offer the best and the efficient services to our customers.

Products & Solutions offered

57

58

59

High tech equipment's occupancy sensors automate the switching or dimming of lights by

detecting movement within a space. They bring convenient and the easiest way to eliminate

lighting-related electricity wastage in unoccupied areas of your home or office. They even

automate motor load switching for A/C, fans. Passive Infrared (PIR), Dual-tech (PRI+Ultrasonic)

and dimmable sensors are available for various applications. Passive Infrared (PIR) occupancy

sensors detect motion by sensing temperature profile changes, which is suitable for detecting

large body movements.

The company is dedicated to establishing a “technology + service” type enterprise. Moreover, the

company actively promotes industrialization and marketization process of technological

achievements, in order to develop the enterprise into a distinctive and influential enterprise in

environment protection enterprise of India.

Go Green : Promotes greater energy awareness and control

Easy-to-use, convenient and affordable system.

Experience true comfort

Simple set-up procedures support do-it-yourself configurations

Control and monitor the office, remote control, Mobile Phone or computer.

60

Automatic control systems

Sensitivity

Time

Retrigger & bypass controls.

Energy Saving Device,

Automatic Switch and Security Device.

Detection angle 360°

Detection range 6m at 3m height at 25°C

Sealed optics

Sensitivity control

Lux (Light) level control for operation

Device on Time control from 10 seconds to 35 minutes

61

62

63

64

65

Touch free water taps

Client List

66

67

GREEN ENVIRONMENT RESILIENCE The Medical Institutions campus maintains a very well developed green carper throughout the campus.

Recently more arrangements have been made for better parking.

68

GREEN ENVIRONMENT RESILIENCE Reduction of carbon foot prints in the atmosphere is a challenging task A complete tree survey has been completed with the help of eminent botanists and students in the whole of Medical Institutions campus. The survey is vital in order to understand the distribution of plants and their level of carbon uptake. Plastic free campus The MI campus has announced to be a plastic free campus. Currently plastics are being aggregated but a full fledged plastic waste management is yet to be accomplished.

Mosquito Free Campus

We have consulted with ‘Reach Beyond’ a private entity who is marketing a Russian product

AERO which effectively traps mosquitoes up to a radius of 50000 sq.ft.

69

70

FOOD & HEALTH JSS Institutions are already contributing to the reduction of carbon foot print by following strict vegetarian food habits throughout the entire campus. Further, it is necessary to give orientation to the students regarding the practice of low carbon food and diet. We have already interacted with the hostel officials, care takers and cooks regarding the cleanliness in the kitchen premises. We have received an over-whelming response from the hostel officials requesting for orientation towards cleanliness and best practices.

Modernization of the kitchen equipments is necessary in order to meet the criterion of MHRD for SWACHHTA ranking.

71

SUMMARY As an initiation of Smart Campus at Jagadguru Sri Shivarathreeswara /Academy of Higher Education & Research, 10 key elements have been identified. Initially meetings were held with higher officials regarding the available resources at the institutes. After several rounds of surveying and detailed discussion, we had planned to focus on 5 key elements to kick start the campaign keeping in mind the NAAC visit and SWACHHTA RANKING. In order to educate students on sustainability and green campus, several pilot projects have been initiated. Parallelly, discussions with resource persons were also held on regular intervals. Quotations were invited for Biogas plants and Sewage treatment plants for effective waste management and water recycling. For efficient energy saving, light automation systems were considered and discussed with experts in the field. Phase 1 is planned to be executed at an approximate cost of 10 crores including Skill Development lab, upgradation of basket ball ground, gallery seating ground, biogas plant, sewage treatment plant, light automation etc.

Budgetary Summary

S. No. Project Approx. Cost

1 Skill Development Lab 5 crores

2 Gallery seating Ground 2 Crores

3 Upgradation of Basket ball ground

0.5 Crores

4 Sewage Treatment Plant completion in all campuses

1.6 Crores

5 Biogas Plant in all campuses 25 Lakhs

6 Vermicompost unit in all campuses

10 Lakhs

7 Light/Fan/AC Automation System in all campuses

10 Lakhs

8 Upgradation of Boys Hostel Kitchen

25 Lakhs