Course Module

Department of Agricultural Engineering Faculty of Agricultural Technology Universitas Brawijaya

Module name Agricultural Electricity and Energy Module level Undergraduate program

Code TPE4006

Subtitle -

Courses -

Semester(s) 5 Person

responsible for the module

Dr. Ir. Bambang Dwi Argo, DEA

Lecturer 1. Dr. Ir. Bambang Dwi Argo, DEA 2. Dr. Ir. Bambang Susilo, MSc. Agr 3. Dimas Firmanda Al Riza, ST., MSc.

4. Retno Damayanti, STP., MP.

5. Dewi Maya Maharani, STP., MSc Language Bahasa Indonesia, English

Relation to curriculum

Compulsory/elective Type of

teaching, contact hours

Contact hours and class size separately for each teaching method: lecture, lesson, practical, project, seminar etc.

Workload 136 hours/semester

Lecture, Exercise, Laboratory session, and private study Credit points 3 SKS / 5 ECTS

Requirements according to the

examination regulations

-

Recommended prerequisites

- Module

objectives/inte nded learning outcomes

ILO-1: An ability to use engineering principles in designing technology products related to the field of agricultural engineering science

ILO-6: An ability to conduct research, explore, develop and apply science and technology in the field of agricultural engineering science

Objectives: This course provides an overview of alternative energy sources, biomass energy, wind energy, water energy, solar energy, energy conversion processes, conversion machines, transformers, and the series of diagram combustion theory to value auditing..

Knowledge: familiarity with the concept of alternative energy sources, biomass energy, wind energy, water energy, solar energy, and energy conversion processes

Skills: cognitive – Apply basic knowledge of alternative energy sources, biomass energy, wind energy, water energy, solar energy, energy conversion processes. Phsycomotoric - practical abilities in implementing alternative energy sources, biomass energy, wind energy, water energy, solar energy, energy conversion processes.

Competences: Student able to evaluate energy conversion processes, conversion engine components, and combustion circuit systems.

Content Courses:

1) Introduction to energy and electricity and their role in agriculture 2) Introduction of alternative energy sources

3) The basic theory of biomass energy 4) The basic theory of wind energy 5) The basic theory of water energy 6) The basic theory of solar energy

7) Introduction to the energy conversion process 8) Basic components of the conversion engine 9) Basic theory of transformer

10) Introduction to the circuit system and combustion theory Laboratory practice:

1. Pre-test and laboratory introduction

2. Practical of introduction of energy efficiency of solar cells

3. Practical of introduction to the concept of energy conversion efficiency 4. Practical of introduction of solar cells (Photovoltaic)

5. Practical of introduction to the process of making biodiesel 6. Post-test

Study and examination requirements and forms of examination

1. Midterm exam 2. Final term exam 3. Assignment 4. Group assignment

5. Laboratory Practice Report 6. Laboratory Practice Final Exam How to score:

Midterm Exam(1-5) = 30%

Final Exam (1-4) = 30%

Assignment = 20%

Laboratory Practice (Report, Lab. Exam, Final Project) = 20%

A : 80 < Final Score ≤ 100 B+ : 75 < Final Score ≤ 80 B : 69 < Final Score ≤ 75 C+ : 60 < Final Score ≤ 69 C : 55 < Final Score ≤ 60 D : 50 < Final Score ≤ 55 D+ : 44 < Final Score ≤ 50 E : 0 < Final Score ≤ 44 Media

employed

Class, Online learning system (Zoom and Google Classroom), Laboratory Practice

Reading list 1) Bockisch, H. D. dan Heiman. 1976. Food Chemistry. Springer-Verlag: Berlin dengan Gelombang Ultrasonik. Disertasi-UB. Malang

2) Fessenden, R dan J.S. Fessenden. 1997. Dasar-Dasar Kimia Organik.

Binarupa Aksara: Jakarta

3) Handbook.Vienna: BoersedruckGes.m.bH.

4) Mittlebach, M., Remschmidt, Claudia., 2004, Biodiesel The Comprehensive

5) Ni’ matul Izza, 2011, Aplikasi Gelombang Ultrasonik pada Proses Pengolahan Biodiesel Berbahan Baku Jarak Pagar, Skripsi, Keteknikan Pertanian, FTP, Unversitas Brawijaya

6) Quaschning, V., 2004: Renewable Energy World, Science Publisher, German.

7) Soeradjaja, T. H. 2005. Modifikasi Mesin Atau Kimia. Ketua Forum Biodiesel Indonesia. Subbid Promosi Karya Ilmiah LIPI.

8) Susilo, B. 2008. Model Kinetik Transesterifikasi Minyak Sawit Menjadi Biodiesel

9) Vicente, G., Martinez, M., Aracil, J. 2006. A Comparative Study of Vegetable Oils for Biodiesel Production In Spain. Energy and Fuels, 20, 394-398