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Plan de estudios: DEGREE IN CHEMICAL ENGINEERING
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DEGREE IN CHEMICAL ENGINEERING

Code:
 C204

Credits:
 240
 
Publication date:
 22/03/2012

Title:
 Undergraduate 3-5 years (ECTS)
 
Fee:
 22,18
 1st-registration credits
 
European Accreditation of Engineering Programmes  EUR-ACE

FIELD OF STUDY

Engineering and Architecture

SYLLABUS

DEGREE IN CHEMICAL ENGINEERING

TYPE OF EDUCATION

Face-to-face

LANGUAGE / S THAT IS OFFERED

Valencian
Spanish
English

CENTRES WHERE IT IS TAUGHT

University Polytechnic

PROGRAMME JOINTLY SHARED WITH

Only taught at this university

EXAMINATION DATES

Enter the list of examination dates for this graduate programme.

SYLLABUS OFFERED

 

Legend: Not offeredNo teaching
FIRST YEAR
SECOND YEAR
THIRD YEAR
FOURTH YEAR

 

GENERAL AIMS OF THE DEGREE COURSE


The Degree in Chemical  Engineering has been designed with the basic aim of producing professionals capable of applying scientific methods and the principles of engineering and economics to addressing and solving complex problems regarding the design of products and processes in which materials undergo changes in morphology, composition or energy content. This includes the design, calculation, construction, implementation and operation of equipment and installations where such processes are carried out, and which are characteristic of the chemical industry and related sectors, such as the pharmaceutical, biotechnological, food or environmental sectors. All the foregoing implies considerations of quality, safety, economy, rational and efficient use of natural resources and preservation of the environment, in compliance with professional codes of conduct.

The aim is to produce graduates who are highly knowledgeable and skilled, with a creative approach and an awareness of the need for professional development in the course of their own work and that of their colleagues. Accordingly, learning skills and the capacity to apply knowledge are just as important as the quantity of knowledge acquired.

COMPETENCES


Regulated Professional Competences

  • CPR1:Capacity to draft, sign and develop industrial engineering projects in the speciality of Chemical Engineering, aimed at the construction, refurbishment, repair, conservation, demolition, manufacture, installation, assembly and exploitation of: structures, mechanical equipment, energy facilities, electrical and electronic installations, industrial installations and plants and manufacturing and automation processes.
  • CPR2:Capacity for managing activities involved in the engineering problems described in the previous heading.
  • CPR3:Understand basic subjects and technologies to allow one to learn new methods and theories, making one versatile in adapting to new situations.
  • CPR4:Capacity to solve problems with initiative, decision-making skills, creativity, critical reasoning and ability to communicate and transmit knowledge, skills and abilities in the field of industrial engineering.
  • CPR5:Understand how to carry out measurements, calculations, assessments, valuations, surveys, studies, reports, work sheets and other similar tasks.
  • CPR6:Capacity to deal with mandatory specifications, regulations and standards.
  • CPR7:Capacity to analyse and assess the social and environmental impact of technical solutions.
  • CPR8:Capacity for organisation and planning in companies and other institutions and organisations.
  • CPR9:Capacity to work in a multilingual, interdisciplinary environment.
  • CPR10:Knowledge, understanding and capacity to apply the necessary legislation when acting as an Industrial Engineer in a professional capacity.
  • CPR11:Capacity to apply quality principles and methods.

General Competences:

    Instrumental

    • CG1:Capacity for analysis and synthesis.
    • CG2:General basic understanding of the profession.
    • CG3:Knowledge of computers in the field of study.
    • CG4:Problem solving.
    • CG5:Decision making.

    Interpersonal

    • CG6:Plan, organise and supervise teamwork.
    • CG7:Work in multidisciplinary teams.
    • CG8:Work in an international context.
    • CG9:Interpersonal relationship skills.
    • CG10:Capacity to communicate with experts in other fields.
    • CG11:Critical reasoning.
    • CG12:Apply the ethical requirements and deontological code of the profession in all situations.

    Systematic

    • CG13:Capacity to put knowledge into practice.
    • CG14:Capacity for self-learning.
    • CG15:Capacity to adapt to new situations.
    • CG16:Ability to work independently.
    • CG17:Creativity in all areas of the profession.
    • CG18:Capacity to make decisions and exercise leadership functions.
    • CG19:Possess initiative and an entrepreneurial spirit.
    • CG20:Motivation for quality.
    • CG21:Awareness of environmental topics.

UA Basic Transversal Competences

  • CT1:Foreign language skills.
  • CT2:Computer and information skills.
  • CT3:Oral and written communication skills.

Specific Competences (CE)

  • CE1:Capacity for solving any mathematical problems that may arise in engineering. Ability to apply knowledge of: linear algebra, geometry, differential geometry, differential and integral calculus, differential equations and partial derivates, numerical methods, numerical algorithms, statistics and optimisation.
  • CE2:Understand and master the basic concepts of the general laws of mechanics, thermodynamics, electromagnetic fields and waves, and their application to solve engineering problems.
  • CE3:Basic understanding of computer use and programming, operating systems, databases and computer programs applicable to engineering.
  • CE4:Capacity to understand and apply the basic principles of general chemistry, organic and inorganic chemistry and their applications in engineering.
  • CE5:Capacity for spatial vision and understanding of graphic representation techniques, both using traditional metric and descriptive geometry methods and computer-aided design applications.
  • CE6:Suitable understanding of the concept of a company, the legal and institutional framework of companies. Company organisation and management.
  • CE7:Understand applied thermodynamics and the transmission of heat. Basic principles and their application to solving engineering problems.
  • CE8:Understand the basic principles of fluid mechanics and their application to solving problems in the field of engineering. Calculation of piping, channels and fluid systems.
  • CE9:Understand basic materials science, technology and chemistry. Understand the relationship between microstructure, synthesis or processing and the properties of materials.
  • CE10:Understand and use the principles of circuit theory and electric machines.
  • CE11:Understand the fundamentals of electronics.
  • CE12:Understand the fundamentals of automatic mechanisms and control methods.
  • CE13:Understand the principles of the theory of machines and mechanisms.
  • CE14:Understand and use the principles of the resistance of materials.
  • CE15:Basic understanding of production and manufacturing systems.
  • CE16:Basic understanding and application of environmental technologies and sustainability.
  • CE17:Applied knowledge of business organisation.
  • CE18:Knowledge and ability to organise and manage projects. Understand the organisational structure and functions of a project office.
  • CE19:Knowledge of material and energy balances, biotechnology, matter transfer, separation operations, chemical reaction engineering, reactor design, valorisation and transformation of raw materials and energy resources.
  • CE20:Capacity to analyse, design, simulate and optimise processes and products.
  • CE21:Capacity to design and manage applied experimental procedures, especially for determining thermodynamic and transport properties, and modelling of phenomena and systems in the field of chemical engineering, systems with fluid flows, heat transmission, matter transfer operations, kinetics of chemical reactions and reactors.
  • CE22:Capacity to design, manage and operate simulation, control and instrumentation procedures for chemical processes.

Basic Competences and Competences included under the Spanish Qualifications Framework for Higher Education (MECES)

  • CB1:Que los estudiantes hayan demostrado poseer y comprender conocimientos en un área de estudio que parte de la base de la educación secundaria general, y se suele encontrar a un nivel que, si bien se apoya en libros de texto avanzados, incluye también algunos aspectos que implican conocimientos procedentes de la vanguardia de su campo de estudio.
  • CB2:Que los estudiantes sepan aplicar sus conocimientos a su trabajo o vocación de una forma profesional y posean las competencias que suelen demostrarse por medio de la elaboración y defensa de argumentos y la resolución de problemas dentro de su área de estudio.
  • CB3:Que los estudiantes tengan la capacidad de reunir e interpretar datos relevantes (normalmente dentro de su área de estudio) para emitir juicios que incluyan una reflexión sobre temas relevantes de índole social, científica o ética.
  • CB4:Que los estudiantes puedan transmitir información, ideas, problemas y soluciones a un público tanto especializado como no especializado.
  • CB5:Que los estudiantes hayan desarrollado aquellas habilidades de aprendizaje necesarias para emprender estudios posteriores con un alto grado de autonomía.

 

CREDIT STRUCTURE OF THE DEGREE COURSE


Subjects in the Degree in Chemical Engineering, each worth 6 or 9 European ECTS credits, are organised into semesters.  Specifically, students are required to take 30 credits each semester, to complete 60 credits per year, for a total of 240 credits over four years.

In order to make the course compatible with other activities, students are allowed to take a part-time course consisting of 30 credits per academic year.


STRUCTURE OF THE COURSE PROGRAMME PER SUBJECT TYPE


Subject type

Credits

Core

60

Compulsory

144

Optional

24

Final Project

12

Total credits

240



GENERAL DESCRIPTION OF THE COURSE PROGRAMME


The University of Alicante Degree in Chemical Engineering Course is organised into a series of Units, based on the structure set out in Royal Decree 1393/2007. These units cover the proficiencies, learning outcomes, educational activities and assessment procedure to be followed in order for students to attain the aims of the Degree.

These units comprise the compulsory aspect of the Degree, and are aimed at enabling students to acquire the proficiencies and knowledge considered essential for Graduates in Chemical Engineering, thus ensuring acquisition of the generic professional skills required for regulated professional practice as Industrial Engineering Technicians. In this regard, the requirements established in Order CIN/351/2009 of 9 February have been observed, concerning validation of official university qualifications which qualify their holders for professional practice as Industrial Engineering Technicians. This Order states that the course programme should include at least the following modules:

- Core Module

- Common Industrial Module

- Specific Technology Module: Chemical Engineering

and which also specifies that a Final Project should be undertaken.

The course has been structured on the basis of three types of subjects:

Firstly, in accordance with Royal Decree 1393/2007, the first half of the course programme contains the core subjects, worth a total of 60 ECTS.

Secondly, there are the compulsory subjects, worth 144 ECTS and aimed at guaranteeing that students acquire the skills associated with the Degree, in addition to 12 ECTS credits pertaining to the compulsory Final Project.  This latter is carried out in the final semester and is aimed at assessing the proficiencies acquired.  Prior to evaluation for the final project, the student must provide evidence of ability in a foreign language.  Among other forms of accreditation, the minimum necessary requirement at the University of Alicante is to have attained level B1 of the European Framework of Reference for Languages, and this requirement may be raised in the future.

Thirdly, the course programme also includes optional subjects worth 24 ECTS. These are specialisation-based and are taken in the final semesters of the course, allowing students to choose their own curricular direction.

As regards optional subjects, a total of 66 optional ECTS credits are offered, in addition to the possibility of carrying out Work Experience. These are taken in semester 8.

Optional subjects include the possibility of carrying out work experience, whether for 6 credits in lieu of one optional subject, or for 12 credits, in lieu of two.


OPTIONAL SUBJECTS


OPTIONAL SUBJECTS

ECTS

EXTENDED MECHANICAL DRAWING

6

INDUSTRIAL AUTOMATION

6

HETEROGENEOUS CATALYSIS AND ELECTROCHEMICAL ENGINEERING

6

INTEGRATED MANAGEMENT IN THE CHEMICAL INDUSTRY

6

MANAGEMENT AND TREATMENT OF INDUSTRIAL WASTES AND WATER

6

ENGLISH I

6

ENGLISH II

6

ELECTRICAL INSTALLATIONS

6

SUSTAINABLE FACILITIES AND RENEWABLE RESOURCES

6

WORK EXPERIENCE I

6

WORK EXPERIENCE II

6

ROBOTICS

6

POLYMER PROCESSING TECHNOLOGY

6

 

 

LANGUAGE REQUIREMENT (IN A FOREIGN LANGUAGE)

Students who study an undergraduate degree at the University of Alicante must confirm a minimum level of B1 in a foreign language (a B2 is recommended) in order to obtain the diploma.  

The required language level is in accordance with the Common European Framework of Reference for Languages. 

The language accreditation requirement can be obtained previously or at any time during university studies. However, the language requirement will be necessary in order to be able to assess the final year project.

The different forms of obtaining such language requirement can be consulted in the additional information in this section.  

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LANGUAGE TEACHING COMPETENCE CERTIFICATE

Students who want to have a career in non-university teaching when they finish their studies are recommended to obtain the teaching competence certificate (Valencian and/or foreign languages).

This certificate can be obtained by taking specific itineraries in your university studies or by taking the UA teaching competence course in Valencian, German, French and English.

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FINAL YEAR PROJECT (TFG)

All the official undergraduate degrees must be completed by preparing and defending a final year project, which must be done in the final phase of the studies and be aimed at the assessment of competences associated to the degree.

The final year project must be an original, independent and personal work. The elaboration of it may by individual or coordinated. Each student will prepare this project under the supervision of a tutor, allowing students to show the received training content in an integrated many, as well as the acquired competences associated to the undergraduate degree.

In order to register in the final year project, students must comply with the requirements established in the “Regulations for continuation studies for students registered in undergraduate degrees at the University of Alicante”. Among the requirements established to be able to register in the final year project, a minimum of 168 credits must be passed in undergraduate degrees with a total of 240 credits, and a minimum of 228 credits in undergraduate degrees with a total of 300 credits or more.

In order for the final year project to be assessed, a B1 level of a foreign language (B2 is recommended) must be confirmed.

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ACCESS ROUTES

Admission to this degree course is open to any applicant who meets one of the following entrance requirements:

1.     SPANISH BACCALAUREATE (LOMCE) UNIVERSITY ENTRANCE EXAM (PAU): Although students can access university by means of any Baccalaureate specialization, the recommended one is Sciences.

Admission scores for this degree can be improved by taking the specific modules of the University Entrance Exam (PAU) as indicated in the table below with their respective weightings.

TABLE 1

Chemical Engineering

2.     PREVIOUS BACCALAUREATES WITH OR WITHOUT A PASS IN THE UNIVERSITY ENTRANCE EXAM (PAU): Students who have completed their Baccalaureate under previous education systems and have passed the PAU will be able to use the mark obtained in their application.

However, students can take specific exam modules during the voluntary PAU exam period in order to improve their admission score as shown in table 1. They can also sit for the obligatory PAU exams, in which case they will have to take all the exams scheduled during this period.

3.     VOCATIONAL EDUCATION: Vocational educational qualifications such as senior technician, senior technician of plastic arts and design, or senior technician in sports is the preferred professional area although access to this degree may be through any professional field.

Admission scores can be improved by taking the PAU exam in up to 4 of the modules in table 1.

4.     STUDENTS FROM EDUCATION SYSTEMS IN COUNTRIES OF THE EUROPEAN UNION OR OTHER STATES WITH WHICH SPAIN HAS AN INTERNATIONAL AGREEMENT: Accreditation is required and issued by Universidad Nacional de Educación a Distancia (UNED).

Students can sit for exams in subjects included in the Pruebas de Competencias Específicas (PCE), organised by the UNED, in order to improve their admission score up to 14 points as indicated in the weightings in Table 1.

5.     STUDENTS FROM FOREIGN EDUCATION SYSTEMS: Prior to applying for the validation of their foreign Baccalaureate, students may sit for up to 4 exams in subjects offered by the Pruebas de Competencias Específicas (PCE) organised by UNED (at least one subject from the core subjects).

The weightings indicated in table 1 will be applied to core and/or optional subjects.

6.     OTHER: University degrees and other similar qualifications. University entrance exam for students over 25 (preferential option: Engineering and architecture). Access on the basis of professional experience (applicants over 40 years of age). Access to applicants aged 45 years or more by means of an exam.

Weightings of the subjects of the specific phase of the Proof of Access to the University (PAU) in the previous years

High School Diploma Subjects

Parámetros de ponderación
Análisis Musical II Biología Ciencias de la Tierra y Medioambientales Dibujo Artístico II Dibujo Técnico II Diseño Economía de la Empresa Electrotecnia Física Geografía Griego Historia de la Música y de la Danza  Historia del Arte Latín Lenguaje y Práctica Musical Literatura Universal Matemáticas Aplicadas a las Ciencias Sociales II Matemáticas II Química Técnicas de Expresión Gráfico Plásticas Tecnología Industrial II

Academic Years 2010-11

2011-12

0.1                                          
0.2
x
x

x  x  x
x
x
                x
x
  x

Academic Years

2012-13

2013-14

2014-15

2015-16

2016-17

0.1
x
x


 x  x

               

 
0.2    
  x
 
 x  x                 x
x    x

 


PROCEDURE FOR APPLYING FOR ADMISSION: PRE-ENROLMENT AND REGISTRATION

  • Anticipated number of places offered during the first pre-enrolment session: 60 
  • Applicants admitted to a course must formally register within the timescale established annually in the enrolment calendar. Registration Information.


RECOMMENDED APPLICANT PROFILE

 

As regards the recommended educational background for the Degree in Chemical Engineering, new students should have a basic grounding in mathematics, physics, chemistry and drawing.

Among the qualities the future Chemical Engineering student should possess, the following are of especial relevance:

  • Capacity for work (perseverance, method and rigour).
  • Capacity for reasoning and critical analysis.
  • Scientific spirit.
  • Capacity to obtain, interpret and apply knowledge.
  • Problem-solving skills.
  • Capacity for synthesis and abstraction.
  • Recommended complementary education: English and user-level computing skills.

 

NUMBER OF PLACES AND PASS MARKS

 

COURSES

NUMBER

OF

PLACES

PASS MARKS

GENERAL

OVER

25

OVER

40

OVER

45

GRADUATES

SPORTSPEOPLE

DISABLED

2010-11

60

6,160

5,600

---

---

---

---

---

2011-12

60

7,136

5,628

---

---

5,000

---

---

2012-13

60

8,072

5,000

---

---

5,000

---

---

2013-14

60

7,229

5,000

---

---

---

---

---

2014-15

60

8,020

---

---

---

---

5,000

5,000

2015-16

60

7,643

---

---

---

---

7,042

---

2016-17

60

8,204

5,000

---

---

5,000

5,000

---

 
  • "Pass marks" indicated correspond to the results of the first adjudication of June.
  • The definitive marks can be inferior to the here collected.

 

PROFESSIONAL PROFILES

 

Graduates in Chemical Engineering are qualified to work in the manufacturing industry, design and consultancy companies, technical, legal or commercial advisory services, administration, teaching and as self-employed industrial engineer technicians, and to issue reports and expert opinions.

On the basis of the proficiencies and professional profile of Chemical Engineers:

a) Graduates in Chemical Engineering are fully qualified to install  facilities and auxiliary services in the chemical industry, particularly as regards the installation of heating, air-conditioning and cooling facilities, sound-proofing, electrical installations, gas and fuel distribution, storage of chemical products, storage of pressurised liquids, water supply facilities, rain-water, waste-water and industrial water installations, fire-prevention installations and pollution control and prevention facilities.

b) Graduates are particularly qualified to participate in the planning and development of chemical processes, applying their scientific and technological grounding to these processes and their products, particularly with regard to production and technical production control, installation and set-up, operation, maintenance and inspection, quality, data-processing, commerce, and the manufacture of equipment and machinery.

c) Graduates are also qualified to write up projects, studies, reports, specifications and procedures within the economic, environmental, and chemical industry, corporate and labour fields, particularly with regard to environmental impact studies, acoustic studies,  waste treatment, management and assessment,  treatment and use of the complete water cycle, pollution control and prevention, eco-efficiency and eco-design of processes and products, sustainable development, technical, economic and market viability studies, process control, equipment, simulation and optimisation, management of industrial hazards and health and safety in the industry, consultancy, technical assessments and reports in legal, official and private matters, homologation; chemical verification, analysis and testing.

d) Likewise, graduates may work in Public Administration and public organisations, as envisaged in the corresponding regulations, and in engineering and consultancy companies.

e) Chemical Engineering graduates are particularly qualified to sign off on the installations referred to in the foregoing paragraphs.

In general, Graduates in Chemical Engineering Industrial Chemistry are qualified to work as regulated Industrial Engineering Technicians, given that the proposed Course Programme complies with the terms of Order CIN/351/2009 of 9 February establishing the requirements for the validation of official university titles which qualify their holders to exercise as Industrial Engineering Technicians.


IMPLEMENTATION


The proposed course programme for the University of Alicante Degree in Chemical Engineering will be implemented year by year. This involves phasing out and replacing each year of the Degree in Chemical Engineering programme currently being taught at the University of Alicante Science Faculty (amended 1999 programme). Subjects pertaining to the former degree will no longer be taught once those of the new Degree Course in Chemical Engineering have been implemented.


Implementation of the new University of Alicante Degree (Grado) in Chemical Engineering course will begin in the academic year 2010-2011.

TIMESCALE

Academic Year

Implementation of the new Degree (Grado) in Chemical Engineering

Phasing out of the current Degree in Chemical Engineering

2010-11

1st Year

1st Year

2011-12

2nd Year

2nd Year

2012-13

3rd Year

3rd Year

2013-14

4th Year

4th Year

2014-15

----

5th Year


CREDIT EQUIVALENCE BETWEEN SUBJECTS ON THE CURRENT COURSE PROGRAMME AND THE NEW DEGREE (GRADO) IN CHEMICAL ENGINEERING


Subjects in Chemical Engineering

Subjects in the Degree in Chemical Enginneering

GRAPHIC EXPRESSION (7.5 credits)

Graphic Engineering (6 ECTS)

PHYSICAL BASES OF ENGINEERING I (4.5)

Physical Bases of Engineering II (6)

PHYSICAL BASES OF ENGINEERING II (6)

Physical Bases of Engineering I (6)

MATHEMATICAL BASES OF ENGINEERING (16.5)

Mathematical Bases of Engineering I (6)

PHYSICAL CHEMISTRY (7.5)

Extended Chemistry (6)

FUNDAMENTALS OF ANALYTICAL CHEMISTRY (7)

Extended Chemistry (6)

FUNDAMENTALS OF ORGANIC CHEMISTRY (7)

Chemical Bases of Engineering (6)

STRUCTURE AND PROPERTIES OF MATERIALS (7)

Chemical Bases of Engineering (6)

INTRODUCTION TO CHEMICAL ENGINEERING (8.5)

Introduction to Chemical Engineering (6)

EXPERIMENTS IN CHEMICAL ENGINEERING II (5) AND EXPERIMENTS IN CHEMICAL ENGINEERING III (6)

Experiments in Chemical Engineering (9)

INORGANIC CHEMISTRY (6.5)

Applied Inorganic Chemistry (6)

ORGANIC CHEMISTRY (6.5)

Applied Organic Chemistry (6)

APPLIED THERMODYNAMICS AND CHEMICAL KINETICS (9)

Applied Physical Chemistry (6)

EXTENDED MATHEMATICS FOR ENGINEERING (13.5)

Mathematical Bases of Engineering II and III (12)

FLUID MECHANICS (5.5)

Fluid Flow Operations (9)

ANALYTICAL CHEMISTRY (6.5)

Fundamentals of Chemical and Instrumental

Analysis (6)

HEAT TRANSMISSION (4.5) AND THERMOTECHNICS (4.5)

Thermal Engineering (6)

FUNDAMENTALS OF ELASTICITY AND STRENGTH OF MATERIALS (6)

Mechanical design (6)

DESIGN OF EQUIPMENT AND FACILITIES (6)

Extended Mechanical Design (6)

INDUSTRIAL ORGANISATION AND

ECONOMICS (6)

Economics Applied to the Chemical business (6)

ENVIRONMENTAL ENGINEERING (6.5)

Environmental Technology (6)

SEPARATION PROCESSES (7.5)

Separation Processes in Material Transference II (6)

INDUSTRIAL CHEMISTRY (4.5)

Chemistry and Industrial Safety (6)

INDUSTRIAL SAFETY AND HYGIENE (4.5)

Chemistry and Industrial Safety (6)

CHEMICAL REACTORS (7.5)

Reactor Design I (6)

FUNDAMENTALS OF SEPARATION PROCESSES (7.5)

Separation Processes in Material Transference I (6)

CHEMICAL PROCESS EQUIPMENT AND CONTROL (6)

Process Control (6)

EXPERIMENTS IN CHEMICAL ENGINEERING IV (13)

Experiments in Chemical Engineering II (6)

SIMULATION AND OPTIMISATION IN CHEMICAL PROCESSES (6)

Simulation, Optimisation and Design of Chemical Processes (6)

DESIGNING HETEROGENEOUS REACTORS (4.5)

Reactor Design II (6)

HETEROGENEOUS CATALYSIS (4.5) AND ELECTROCHEMICAL REACTORS (4.5)

Heterogeneous Catalysis and Electrochemical Engineering (6)

MANAGEMENT AND TREATMENT OF TOXIC AND DANGEROUS WASTE (4.5)

Management and Treatment of Industrial Waste and Water (6)

MANAGEMENT AND TREATMENT OF WATER (4.5)

Management and Treatment of Industrial Waste and Water (6)

MANAGEMENT AND TREATMENT OF URBAN WASTE (4.5)

Management and Treatment of Industrial Waste and Water (6)

UNIT OPERATIONS IN POLYMER PROCESSING (4.5)

Technology of Polymer Processing (6)

WORK EXPERIENCE IN CHEMICAL ENGINEERING (6)

Work Experience I (6)

INTRODUCTION TO EXPERIMENTS IN PHYSICS (6) AND EQUIPMENT TECHNIQUES IN

PHYSICS (6)

Electrotechnology and Electronics (6)

ELECTROTECHNOLOGY (4.5) AND EQUIPMENT TECHNIQUES IN PHYSICS (6)

Electrotechnology and Electronics (6)

INTRODUCTION TO EXPERIMENTS IN PHYSICS (6) AND ELECTROTECHNOLOGY (4.5)

Electrotechnology and Electronics (6)

BIOCHEMISTRY (7.5)

Biochemical Engineering (6)

PROJECTS (6)

Degree's Final Project (6)

TOTAL: 290,5 Credits

TOTAL: 246 ECTS


According to University of Alicante regulations, students who do not wish to take the new degree course subjects are entitled to sit four examinations in the two academic years following the end of each year. Any students wishing to continue their studies after sitting and failing these tests will be required to follow the new plan, according to the adaptation system established in the new plan. Old (LRU) and new (ECTS) credits are one-to-one equivalent, although overall limits will be established for the credit equivalence system.

 

Credits taken by Chemical Engineering students not listed in the above table may be validated by means of:

 

1. Degree course optional credits, up to the maximum number of optional credits established for each degree course.

 

2. Recognised free-elective credits validated for university, cultural or representational activities will be validated for the degree course, with a maximum of up to 6 academic credits to be validated for various activities, as set out in Art. 12.8 Royal Decree 1393/2007 (participation in cultural, sporting, student representation, charity and cooperation activities).

 

 

 

DEGREE IN CHEMICAL ENGINEERING. SYLLABUS SUMMARY

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