Agricultural Engineering

Opportunity for Agricultural Engineering Students: Master's Thesis Grant Support Under NLRP II

Are you pursuing a Master’s degree in Agricultural Engineering and looking for financial support to conduct impactful research? Here’s a great opportunity for you!

Caritas Nepal, through the Nepal Livelihood and Resilience Program-Phase II (NLRP II), is offering thesis research grants to support innovative work in sustainable agriculture and climate resilience. This program, funded by Caritas Australia and Australian Aid, aims to enhance the well-being and resilience of vulnerable farming communities in Nepal, and they are inviting master’s students to contribute through their research.

Why Agricultural Engineers Should Apply:

The field of Agricultural Engineering closely aligns with several of the program's priority research areas, particularly:

Testing Climate-Smart Technologies on Farmers' Fields – Work with cutting-edge technologies that enhance productivity and reduce the impact of climate change on farming communities.
Women’s Labor Burden in Agriculture – Design and test technologies that reduce the physical demands placed on women in agriculture, ensuring that farming becomes more equitable and efficient.
Small-Scale Mechanization in Agriculture – Develop innovative small-scale machines and tools that can be easily adopted by local farmers to improve efficiency and productivity.

If these topics resonate with your academic interests and expertise, this grant provides a fantastic platform to bring your ideas to life while contributing to real-world solutions for Nepal’s agricultural sector.

Grant Details:

Amount: NRs 150,000 (including tax)
Deadline for Submission: October 15, 2024
Thesis Draft Deadline: June 2025

The grant can be used for research-related expenses such as travel, fieldwork, advisor visits, and thesis printing.

How to Apply:

Submit your application via email or courier to the addresses provided below. Be sure to label your email or mail subject as "Thesis Grant Application/NLRP II".

Email Submission:

Send your application to vacancy@caritas.org.np
Subject: "NLRP II Masters' Thesis Grant Support"

Courier Submission:

Program Coordinator, NLRP II
Caritas Nepal Central Office, Dhobighat, Lalitpur, Nepal
Phone: 01-5438172, 01-5439344

Deadline to Apply: October 15, 2024

This is a valuable opportunity for Agricultural Engineering students to conduct meaningful research while directly contributing to the resilience of Nepal's agricultural communities. Don’t miss out!

Full notice

Original notice of Call for Master's Thesis Grant Support Under Nepal Livelihood and Resilience Program - Phase II (NLRP II)

Call for Master's Thesis Grant Support Under Nepal Livelihood and Resilience Program - Phase II (NLRP II)

Agricultural Engineering Internship Precision Agriculture Syllabus

Revised Course for Agricultural Engineering at Tribhuvan University, Nepal

Agricultural Engineering has been a part of Tribhuvan University’s academic offerings since its introduction in 2002 AD (2057 BS) at Purwanchal Campus, Institute of Engineering, Dharan. Since then, the curriculum has undergone several updates, including a major revision in 2012 AD (2068 BS). Now, in 2024 AD (2081 BS), the course structure has been updated again to align with the evolving demands of the agricultural sector.

Why the Curriculum Needed Revision:

Wave of Agricultural Mechanization: The field is witnessing a rapid adoption of mechanized farming practices.
Internship Program for Skill Development: There has been a growing demand for hands-on, practical experience in the industry.
Emerging Technologies: The global agricultural landscape is evolving with new technologies like precision agriculture and sustainability-focused engineering solutions.

If you want to view the previous syllabus from 2012 AD, visit this link.

Major Revisions:

Added a 12-week Internship Program to enhance practical skills.
New Subject: "Precision Agriculture" introduced to focus on the application of technology for optimizing farm productivity.
New Subject: "Agricultural Engineering for Sustainable Development" to address the role of engineering in promoting sustainable agricultural practices.
Merged Courses:
- "Basic Electrical" and "Basic Electronics"
- "Engineering Professional Practice" and "Project Management"
Removed Courses:
- "Electric Systems and Machines"
- "Climate Change and Adaptation Measures"
- "Field and Industrial Training"
Increased Internal Assessment Marks: The weight of internal assessments has been raised to 40% from 20% of theory marks.
Elimination of Final Practical Exams: Almost all subjects have removed final practical exams, emphasizing continuous assessment.

Minor Revisions:

Shuffling of course schedules and content adjustments.
Changes in subject codes.

Teaching Schedule & Examination Scheme:

Each course is assigned credit hours for lectures (L), tutorials (T), and practicals (P). Here's a snapshot of the courses in the revised curriculum:

L=lecture, T=Tutorial, P= Practical

Year I, Part I

SN. Subject code, Subject Name;Course Credit (L:, T:, P:)

SH 101, Engineering Mathematics I; 3 (L: 3, T: 2)
SH 103, Engineering Chemistry; 3 (L: 3, T: 2, P: 3)
CT 101, Computer Programming; 3 (L: 3, T: 1, P: 3)
ME 106, Engineering Workshop; 2 (L: 1, T: 1, P: 3)
ME 101, Engineering Drawing; 4 (L: 2, T: 2, P: 4)
CE 101, Engineering Mechanics; 4 (L: 4, T: 2)
AE 101, Agricultural Engineering for Sustainable Development; 2 (L: 2, T: 1)

Year I, Part II

SH 151, Engineering Mathematics II; 3 (L: 3, T: 2)
SH 152, Engineering Physics; 4 (L: 4, T: 2, P: 1)
EE 153, Basic Electrical and Electronics Engineering; 3 (L: 3, T: 1, P: 1)
ME 151, Engineering Thermodynamics I; 3 (L: 3, T: 1, P: 1)
CE 155, Fluid Mechanics; 4 (L: 4, T: 2, P: 1)
AE 151, Engineering Materials; 2 (L: 2)
AE 152, Soil Science; 3 (L: 3, T: 1, P: 2)

Year II, Part I

SH 201, Engineering Mathematics III; 3 (L: 3, T: 2)
CE 206, Hydraulics; 4 (L: 4, T: 2, P: 1)
CE 207, Engineering Survey; 3 (L: 3, T: 1, P: 4)
ME 207, HVAC and Cold Storage; 3 (L: 3, T: 1, P: 1)
AE 201, Crop Production Technology; 2 (L: 2, T: 1, P: 1.5)
AE 202, Farm Power and Engine System; 3 (L: 3, T: 1, P: 2)
AE 203, Engineering Properties of Biomaterials; 2 (L: 2, T: 1.5)

Year II, Part II

SH 251, Communication English; 3 (L: 3, T: 1, P: 4)
SH 252, Probability and Statistics; 3 (L: 3, T: 1, P: 4)
SH 253, Numerical Methods; 3 (L: 3, T: 1, P: 3)
CE 257, Strength of Materials and Theory of Structures; 3 (L: 3, T: 2, P: 1)
CE 258, Soil Mechanics and Foundation Engineering; 3 (L: 3, T: 1, P: 2)
CE 259, Survey Camp; 2
AE 251, Renewable Energy and Conversion Devices; 3 (L: 3, T: 1, P: 2)
AE 252, Tractor Systems and Control; 3 (L: 3, T: 1, P: 2)

Year III, Part I

ME 307, Theory and Design of Machine Elements; 3 (L: 3, T: 1, P: 1)
AE 301, Hydrology and Agricultural Meteorology; 3 (L: 3, T: 1, P: 2)
AE 302, Farm Machinery and Equipment; 3 (L: 3, T: 1, P: 2)
AE 303, Agri-Economics and Entrepreneurship; 2 (L: 2, T: 1, P: 1)
AE 304, Irrigation and Drainage Engineering; 3 (L: 3, T: 1, P: 2)
AE 305, Postharvest Engineering; 3 (L: 3, T: 1, P: 2)
AE 306, Field Operation and Maintenance of Farm Machines; 1 (L: 1, P: 3)

Year III, Part II

CE 357, Design of Structures; 3 (L: 3, T: 2, P: 1.5)
AE 351, Soil and Water Conservation Engineering; 3 (L: 3, T: 1, P: 2)
AE 352, Groundwater Development and Tube Well Technology; 3 (L: 3, T: 1, P: 1.5)
AE 353, Dairy and Food Engineering; 3 (L: 3, T: 1, P: 2)
AE 354, Farm Structures and Building Technology; 3 (L: 3, T: 1, P: 1.5)
AE 355, Precision Agriculture; 2 (L: 2, T: 1, P: 1)
AE 365, Elective I; 3 (L: 3, T: 2, P: 1)

Year IV, Part I

AE 411, Project Engineering and Professional Practice; 3 (L: 3, T: 2)
AE 412, Rural Infrastructure Engineering; 3 (L: 3, T: 2)
AE 413, Estimating and Costing; 2 (L: 2, T: 2)
AE 414, Agricultural Extension and Rural Development; 3 (L: 3, T: 1, P: 1)
AE 425, Elective II; 3 (L: 3, T: 2, P: 1)
AE 435, Elective III; 3 (L: 3, T: 2, P: 1)
AE 415, Project I; 2

Year IV, Part II

AE 461, Project II; 2
AE 462, Internship; 4

The revised curriculum is designed to equip students with both theoretical knowledge and practical skills, making them ready for the evolving challenges in agricultural engineering. From an emphasis on sustainability to the integration of new technologies, this updated syllabus is expected to provide a holistic education experience for future engineers.