Sanitary engineering, due to its importance, is considered in many countries as a separate career, in other countries it is considered a specialization of hydraulic engineering. It is responsible for designing, building and operating:.

• - Drinking water supply systems, in all their components, intended for the collection of water from rivers or lakes, relating here to river engineering, to the distribution of purified water to users.

• - Sanitary sewage systems and wastewater treatment plants, including structures intended for returning properly treated water to the environment.

• - Comprehensive solid waste management systems.

The Sanitary Engineer has solid knowledge of hydraulics, and also masters the physical, chemical and bacteriological processes related to water treatment "Water treatment (alternative technologies)"), both for its purification and for its decontamination before being returned to the environment.

Sanitary Engineering arose from the apparent problem that the health and well-being of a population are closely related to the quality of its environment; people have applied certain principles to try to improve the latter. The Romans built aqueducts to prevent droughts and provide the city of Rome with a source of clean, healthy water.

Today's Sanitary engineering had its first mild appearances in London in the mid-19th century, when it was established that an adequate sewage network could reduce the incidence of waterborne diseases such as cholera. The introduction since then of water purification and wastewater treatment has transformed waterborne diseases from leading causes of death to rarities in industrialized countries.

The name Sanitary Engineering comes from Anglo-Saxon practice and its origin dates back to the beginning of the 20th century when some of the universities in the United States developed and put into practice a new concept of Public Health, where great attention was paid to the role that basic sanitation plays in promoting the health of populations. These ideas, collected and expanded by the World Health Organization, remain valid and have made it possible to establish as a basic element in estimating the quality of life of citizens, the availability of an adequate supply of drinking water and wastewater disposal. These were the fundamental considerations in the definition of the Engineer, adopted in 1970 by the International Labor Organization and whose essential part is expressed as follows:

"Designs the construction of engineering works and facilities intended to ensure public hygiene and health, such as water supply and waste evacuation systems, and plans, organizes and supervises their construction, operation, conservation and repair; performs tasks similar to those carried out by the Civil Engineer, in general, but is specialized in the design, construction, operation, conservation and repair of drinking water filtration and distribution facilities, wastewater evacuation systems."

With this background, we understand the dependence of Sanitary Engineering on the career that gave it its origin, a situation that persists in university training programs, to a greater or lesser degree. It is up to the academic authorities to examine whether it is pertinent to modify the previous definition, to make way for the demands of modern technology and what is classified as the “new environmental dimension” of this knowledge; This new vision of the career has been specified in the following definition adopted by the Universidad del Valle: “Health Engineering is understood as the profession in which, through the application of the scientific method to the interpretation of natural and social phenomena, models applicable to the conditions of human beings are developed, in search of improving their health.”

The beginning of the practice of Sanitary Engineering in Colombia occurred in the 1940s with the creation of the Municipal Development Fund, oriented towards aqueduct and sewage projects. In the 1950s, it was projected with the creation of the Municipal Development Institute and the birth of the Colombian Association of Sanitary and Environmental Engineering, Acodal.

The Sanitary Engineering program emerged in the 1960s as a product of the separation of profiles between Civil Engineering and Chemical Engineering, in which the environmental component did not find its own identity, in a context in which the need for housing and the use of appropriate and low-cost technologies urgently imposed the emergence of this type of programs.

In 1960, the Faculty of Engineering of the National University revealed a report that showed the need for Sanitary Engineers to solve problems of aqueduct, sewage and basic sanitation coverage. In 1962, the first degree program emerged at the Universidad del Valle, and at the University of Antioquia it was created on February 1, 1968 and began studies in the first semester of 1969. Sanitary Engineering studies were developed from Civil Engineering and Public Health, focused on basic sanitation, epidemiology, public health, aqueducts and sewage. In 1978, issues such as air pollution and urban cleanliness were involved. At the end of the 90s, several electives were introduced that included topics on Environmental Management and the provision of Public Services.

For the period from 1983 to 1986, the National Development Plan called “Change with Equity” was implemented, which contemplates in many of its sections the improvement of the quality of education and “the improvement of research on the social and economic characteristics of teaching in Colombia and advances in the philosophy and pedagogy of science.” Likewise, the aforementioned plan states that "The Ministry of Education will create the National Open University system to diversify the offer of programs that satisfy the needs of the various Colombian regions." At the local level and at the beginning of the 1980s, the investment plan of the Department of Boyacá defined aqueducts and sewers as investment priorities, to reduce one of the causes of high mortality and improve the hygiene and health conditions of the population, which at the time 69% of the towns with less than 2,500 inhabitants did not have aqueduct service and 90% lacked sewage services.

Within this framework of ideas, the Sanitary Engineering program was born as a response to a felt need that the country has to solve various and complex environmental sanitation problems, mainly those related to the supply of quality water, disposal of liquid and solid waste and the control of emissions into the atmosphere.

In Portugal, the first publications on health and public health have been developed by Ricardo Jorge in 1884, later, the engineers Antonio Lobato de Faria, Pedro Celestino da Costa, among others, contributed to the development of sanitary engineering in Portugal.

The oldest school of Sanitary Engineering in Portugal is the Faculty of Science and Technology, New University of Lisbon. This university currently grants the degree of Doctor in Sanitary Engineering. The first sanitary engineers to emerge in Portugal studied at this university as a postgraduate.

One of the main poles of development of applied research in the Sanitary Engineering Center of Sanitary Engineering LNEC - National Laboratory of Civil Engineering.

Sanitary Engineering has a partnership with APESB (Portuguese Association for the Study of Sanitation).

Antonio Lobato de Faria was the first president of the institute.

The approach under which the training objectives and curricular development of Sanitary Engineering are guided is due to a reflection process in which the international context, the millennium goals set by the United Nations and the dynamics in the national and regional context are analyzed in accordance with advances in engineering and local needs, in accordance with the above, it seeks to direct a training process that presents:

• - Bases of Civil Engineering in relation to the design of structures and knowledge of engineering materials.

• - Conceptual bases and strength in fluid mechanics and Hydraulics.

• - Strengths in biological), environmental and unitary processes.

• - Foundation in Thermodynamics, Physics, Mathematics and biology, microbiology.

• - Fundamentals of Chemistry and Environmental Chemistry").

• - Approach to the soil in terms of bearing capacity and foundation in geology.

• - Conceptual elements that allow exploration, exploitation, treatment and distribution of groundwater.

• - Availability of groundwater. Aquifer hydraulics.

• - Training in hydrogeology.

• - Focus on the hydrology of strategic ecosystems based on the availability of water in aquifers and the design of water supply and collection systems.

• - Design of irrigation districts, field support (dams, distribution, flow management "Flow (fluid)")).

• - Focus on sustainable development towards construction processes with community participation.

• - Basic rural and urban sanitation.

• - Strength in solving problems associated with water resources and comprehensive solid waste management.

• - New technologies, water resource modeling and project automation.

• - Elements typical of the profile of every Sanitary Engineer in the national and international context.

The Sanitary Engineering professional presents skills specific to the discipline and a solid comprehensive training oriented towards social commitment, which allows him to enter the labor market as a manager, designer, operator, Builder&action=edit&redlink=1 "Constructor (profession) (not yet written)"), administrator, coordinator or evaluator of health projects within the framework of sustainable development, generating alternative solutions to the problems of water supply for various uses, atmospheric pollution, collection, treatment, reuse and final disposal of liquid and solid waste that affect rural and urban communities at the local, regional, national and international level.

• - Develop your professional activities with a high degree of sensitivity and social commitment.

• - Combine the concepts of basic sciences with applied areas oriented towards the processes carried out in the field of Health Engineering.

• - Innovate, analyze and develop activities, tasks and projects with creativity.

• - Show initiative towards permanent updating in scientific and technological advances.

• - Generate technical and social alternatives for the recovery and preservation of the environment.

• - Possess a comprehensive vision to identify, interpret and propose alternative solutions to health and environmental problems.

• - Demonstrate interest in the development of innovative, appropriate and easily accessible proposals and technologies for the community that become concrete solutions to the environmental problems addressed.

The engineer is a professional who synthesizes a whole series of scientific, technological and technical knowledge to solve social problems in a specific field of action. The engineer is the bridge between needs and solutions. The most important part of your training is the development of the ability to handle and apply physical-mathematical models of reality. Along with this knowledge, you must acquire a series of elements of computing, chemistry, economic, legal and administrative knowledge, along with a whole series of empirical knowledge such as processes and treatments to maintain and conserve the environment.

The Sanitary Engineer will be able to perform professionally as:

• - Project manager, through the application and interpretation of mathematical and computational models that support decision making and generation of alternatives in the context of environmental problems.

• - Designer, builder and administrator of water treatment and distribution systems for human consumption and other uses, in urban and rural populations.

• - Designer, builder and administrator of domestic and industrial wastewater collection, conduction and treatment systems.

• - Designer, builder and administrator of solid waste collection, transportation, treatment and final disposal systems.

• - Designer and/or consultant of air pollution control systems.

• - Operator and/or administrator of public water, sewage or sanitation service companies, as well as health systems and projects that support or optimize the infrastructure of these services in a community.

• - Additionally, you will be able to interact with interdisciplinary research groups, social projection or academic communities of public or private bodies, which carry out projects in the health and environmental field.

The activities of sanitary engineering aimed at cleaning up the environment aim to cut the link in the chain of transmission of many diseases and preserve the environment for the pleasure and well-being of society. This sanitation action is intimately linked to other health disciplines such as:

• - Epidemiology.

• - Parasitology.

• - Statistical microbiology.

• - Health administration.

• - Industrial hygiene.

These are several of the activities in which Sanitary Engineering participates:

• - Water supply, treatment and distribution.

• - Sewage systems, treatment and control of black water (or sewage) and industrial waste.

• - Control of water pollution.

• - Municipal and rural garbage disposal services.

• - Control of rodents and insects.

• - Food hygiene.

• - Sanitation of schools, public places, summer resorts, swimming pools, etc.

• - Construction of hygienic homes.

• - Control of fumes, dusts, gases.

• - Industrial hygiene and sanitation.

• - Planning and urbanization of cities.

• - Civil engineering works, including the areas of hydraulics, structures, topography, geotechnics, foundations.

• - Chemical engineering work, including process and operations areas.

• - Mechanical engineering work, including the areas of design and operation of pumping equipment and equipment for different types of water treatment.

• - Electrical engineering work.

• - Laboratory analysis work") for the determination of physical and chemical parameters and the presence of organic matter.

• - Process and operations research studies.

• - Laboratory studies and work to analyze "bacteriological aspects").

• - Epidemiological studies and awareness-raising activities carried out by doctors specializing in public health.

• - Environmental studies carried out by specialists in environmental impact assessment.

• - Analysis and legal studies.

• - Economic and financial studies.

• - Marketing studies.

• - Social studies.

In the field of job opportunities, it is estimated that future graduates of the Sanitary Engineering program[1]​ will be in demand in the private and state sectors at the local, regional, national and international level.

In employment.com it is stated that the development of infrastructure for the energy, industrial and transportation sectors, the demand for professional services in the area of ​​engineering has increased. Although the Labor Observatory of the Ministry of National Education highlighted that the best occupational prospects are found in the basic cores of knowledge in administration, library science, economics, administrative engineering, mining engineering, electrical engineering, electronic engineering, systems engineering, mathematics and statistics, and medicine, all of these programs are related in their development to the generation of health and environmental problems.

Sanitary Engineering is a program of little dissemination among companies and needs to be consolidated and penetrate the market independently of Environmental Engineering. Sanitary Engineering is a career of the future, since all human activities generate sanitation problems that must be prevented, identified and solved. Internationally, in North America, the greatest demand occurs in the area of Engineering"), among which are earth sciences and focus on the field of life sciences, among others (Observatorio Laboral, 2010). In Argentina, engineering is a profession with excess labor demand. The Graduate Department determined that in 2006, among sixty (60) professionals interviewed, 99% were employed. It is also stated that they have many qualified job positions and an insufficient number of professionals or students to cover them (Universia, 2007).

A study by the Secretary of Economic Development of Bogotá, 2010, indicates that the activities that have the most demand in the capital are those related to transportation, technology and cosmetics, activities that must identify and avoid possible causes of environmental pollution (El Observatorio Nacional de la Universidad Colombiana, 2010). Job creation will be found in the next three or four years, in sectors such as cosmetics and hygiene products, textiles and clothing and agribusiness, forgetting that these activities need the development of health infrastructure and basic sanitation studies.

• - Tchobanoglous G. Sanitary Engineering - Sewer networks and wastewater pumping. Editorial Labor, S.A. 1985. ISBN 84 335 6422 6.

• - Michael Ray Overcash and Dhiraj Ray. Design of Land Treatment Systems For Industrial Wastes. Michigan: Ann Arborscience, 1979.

• - Cheremisinoff, N. P. and P. N. Cheremisinoff, Wafer Treatment and Waste Recovery: Advanced Technologies and Application, Prentice hall Publishers, New Jersey, 1993.

• - Sanitary and Gas Installations Civil Engineering Bahía Blanca Regional Faculty UTN 2005.

• - Sanitary Installations in buildings, 2nd edition, 1995 Enrique Jimeno Blasco.

• - Cold Water Systems, Drainage and Sanitary Facilities, F. Hall 1998,.

• - Hydraulic engineering.

• - Civil Engineering.

• - Environmental engineering.

• - Glossary of Health Promotion - WHO.

• - Sanitary Engineering Portal - Latin America.

• - Portal of Sanitary Engineering in Mexico - Mexico.

• - Colombian Association of Sanitary and Environmental Engineering - Acodal").

• - Univalle Sanitary Engineering - Univalle.

• - Sanitary Engineering University of Boyacá - Uniboyacá").

Sanitary engineering, due to its importance, is considered in many countries as a separate career, in other countries it is considered a specialization of hydraulic engineering. It is responsible for designing, building and operating:.

• - Drinking water supply systems, in all their components, intended for the collection of water from rivers or lakes, relating here to river engineering, to the distribution of purified water to users.

• - Sanitary sewage systems and wastewater treatment plants, including structures intended for returning properly treated water to the environment.

• - Comprehensive solid waste management systems.

The Sanitary Engineer has solid knowledge of hydraulics, and also masters the physical, chemical and bacteriological processes related to water treatment "Water treatment (alternative technologies)"), both for its purification and for its decontamination before being returned to the environment.

Sanitary Engineering arose from the apparent problem that the health and well-being of a population are closely related to the quality of its environment; people have applied certain principles to try to improve the latter. The Romans built aqueducts to prevent droughts and provide the city of Rome with a source of clean, healthy water.

Today's Sanitary engineering had its first mild appearances in London in the mid-19th century, when it was established that an adequate sewage network could reduce the incidence of waterborne diseases such as cholera. The introduction since then of water purification and wastewater treatment has transformed waterborne diseases from leading causes of death to rarities in industrialized countries.

The name Sanitary Engineering comes from Anglo-Saxon practice and its origin dates back to the beginning of the 20th century when some of the universities in the United States developed and put into practice a new concept of Public Health, where great attention was paid to the role that basic sanitation plays in promoting the health of populations. These ideas, collected and expanded by the World Health Organization, remain valid and have made it possible to establish as a basic element in estimating the quality of life of citizens, the availability of an adequate supply of drinking water and wastewater disposal. These were the fundamental considerations in the definition of the Engineer, adopted in 1970 by the International Labor Organization and whose essential part is expressed as follows:

"Designs the construction of engineering works and facilities intended to ensure public hygiene and health, such as water supply and waste evacuation systems, and plans, organizes and supervises their construction, operation, conservation and repair; performs tasks similar to those carried out by the Civil Engineer, in general, but is specialized in the design, construction, operation, conservation and repair of drinking water filtration and distribution facilities, wastewater evacuation systems."

With this background, we understand the dependence of Sanitary Engineering on the career that gave it its origin, a situation that persists in university training programs, to a greater or lesser degree. It is up to the academic authorities to examine whether it is pertinent to modify the previous definition, to make way for the demands of modern technology and what is classified as the “new environmental dimension” of this knowledge; This new vision of the career has been specified in the following definition adopted by the Universidad del Valle: “Health Engineering is understood as the profession in which, through the application of the scientific method to the interpretation of natural and social phenomena, models applicable to the conditions of human beings are developed, in search of improving their health.”

The beginning of the practice of Sanitary Engineering in Colombia occurred in the 1940s with the creation of the Municipal Development Fund, oriented towards aqueduct and sewage projects. In the 1950s, it was projected with the creation of the Municipal Development Institute and the birth of the Colombian Association of Sanitary and Environmental Engineering, Acodal.

The Sanitary Engineering program emerged in the 1960s as a product of the separation of profiles between Civil Engineering and Chemical Engineering, in which the environmental component did not find its own identity, in a context in which the need for housing and the use of appropriate and low-cost technologies urgently imposed the emergence of this type of programs.

In 1960, the Faculty of Engineering of the National University revealed a report that showed the need for Sanitary Engineers to solve problems of aqueduct, sewage and basic sanitation coverage. In 1962, the first degree program emerged at the Universidad del Valle, and at the University of Antioquia it was created on February 1, 1968 and began studies in the first semester of 1969. Sanitary Engineering studies were developed from Civil Engineering and Public Health, focused on basic sanitation, epidemiology, public health, aqueducts and sewage. In 1978, issues such as air pollution and urban cleanliness were involved. At the end of the 90s, several electives were introduced that included topics on Environmental Management and the provision of Public Services.

For the period from 1983 to 1986, the National Development Plan called “Change with Equity” was implemented, which contemplates in many of its sections the improvement of the quality of education and “the improvement of research on the social and economic characteristics of teaching in Colombia and advances in the philosophy and pedagogy of science.” Likewise, the aforementioned plan states that "The Ministry of Education will create the National Open University system to diversify the offer of programs that satisfy the needs of the various Colombian regions." At the local level and at the beginning of the 1980s, the investment plan of the Department of Boyacá defined aqueducts and sewers as investment priorities, to reduce one of the causes of high mortality and improve the hygiene and health conditions of the population, which at the time 69% of the towns with less than 2,500 inhabitants did not have aqueduct service and 90% lacked sewage services.

Within this framework of ideas, the Sanitary Engineering program was born as a response to a felt need that the country has to solve various and complex environmental sanitation problems, mainly those related to the supply of quality water, disposal of liquid and solid waste and the control of emissions into the atmosphere.

In Portugal, the first publications on health and public health have been developed by Ricardo Jorge in 1884, later, the engineers Antonio Lobato de Faria, Pedro Celestino da Costa, among others, contributed to the development of sanitary engineering in Portugal.

The oldest school of Sanitary Engineering in Portugal is the Faculty of Science and Technology, New University of Lisbon. This university currently grants the degree of Doctor in Sanitary Engineering. The first sanitary engineers to emerge in Portugal studied at this university as a postgraduate.

One of the main poles of development of applied research in the Sanitary Engineering Center of Sanitary Engineering LNEC - National Laboratory of Civil Engineering.

Sanitary Engineering has a partnership with APESB (Portuguese Association for the Study of Sanitation).

Antonio Lobato de Faria was the first president of the institute.

The approach under which the training objectives and curricular development of Sanitary Engineering are guided is due to a reflection process in which the international context, the millennium goals set by the United Nations and the dynamics in the national and regional context are analyzed in accordance with advances in engineering and local needs, in accordance with the above, it seeks to direct a training process that presents:

• - Bases of Civil Engineering in relation to the design of structures and knowledge of engineering materials.

• - Conceptual bases and strength in fluid mechanics and Hydraulics.

• - Strengths in biological), environmental and unitary processes.

• - Foundation in Thermodynamics, Physics, Mathematics and biology, microbiology.

• - Fundamentals of Chemistry and Environmental Chemistry").

• - Approach to the soil in terms of bearing capacity and foundation in geology.

• - Conceptual elements that allow exploration, exploitation, treatment and distribution of groundwater.

• - Availability of groundwater. Aquifer hydraulics.

• - Training in hydrogeology.

• - Focus on the hydrology of strategic ecosystems based on the availability of water in aquifers and the design of water supply and collection systems.

• - Design of irrigation districts, field support (dams, distribution, flow management "Flow (fluid)")).

• - Focus on sustainable development towards construction processes with community participation.

• - Basic rural and urban sanitation.

• - Strength in solving problems associated with water resources and comprehensive solid waste management.

• - New technologies, water resource modeling and project automation.

• - Elements typical of the profile of every Sanitary Engineer in the national and international context.

The Sanitary Engineering professional presents skills specific to the discipline and a solid comprehensive training oriented towards social commitment, which allows him to enter the labor market as a manager, designer, operator, Builder&action=edit&redlink=1 "Constructor (profession) (not yet written)"), administrator, coordinator or evaluator of health projects within the framework of sustainable development, generating alternative solutions to the problems of water supply for various uses, atmospheric pollution, collection, treatment, reuse and final disposal of liquid and solid waste that affect rural and urban communities at the local, regional, national and international level.

• - Develop your professional activities with a high degree of sensitivity and social commitment.

• - Combine the concepts of basic sciences with applied areas oriented towards the processes carried out in the field of Health Engineering.

• - Innovate, analyze and develop activities, tasks and projects with creativity.

• - Show initiative towards permanent updating in scientific and technological advances.

• - Generate technical and social alternatives for the recovery and preservation of the environment.

• - Possess a comprehensive vision to identify, interpret and propose alternative solutions to health and environmental problems.

• - Demonstrate interest in the development of innovative, appropriate and easily accessible proposals and technologies for the community that become concrete solutions to the environmental problems addressed.

The engineer is a professional who synthesizes a whole series of scientific, technological and technical knowledge to solve social problems in a specific field of action. The engineer is the bridge between needs and solutions. The most important part of your training is the development of the ability to handle and apply physical-mathematical models of reality. Along with this knowledge, you must acquire a series of elements of computing, chemistry, economic, legal and administrative knowledge, along with a whole series of empirical knowledge such as processes and treatments to maintain and conserve the environment.

The Sanitary Engineer will be able to perform professionally as:

• - Project manager, through the application and interpretation of mathematical and computational models that support decision making and generation of alternatives in the context of environmental problems.

• - Designer, builder and administrator of water treatment and distribution systems for human consumption and other uses, in urban and rural populations.

• - Designer, builder and administrator of domestic and industrial wastewater collection, conduction and treatment systems.

• - Designer, builder and administrator of solid waste collection, transportation, treatment and final disposal systems.

• - Designer and/or consultant of air pollution control systems.

• - Operator and/or administrator of public water, sewage or sanitation service companies, as well as health systems and projects that support or optimize the infrastructure of these services in a community.

• - Additionally, you will be able to interact with interdisciplinary research groups, social projection or academic communities of public or private bodies, which carry out projects in the health and environmental field.

The activities of sanitary engineering aimed at cleaning up the environment aim to cut the link in the chain of transmission of many diseases and preserve the environment for the pleasure and well-being of society. This sanitation action is intimately linked to other health disciplines such as:

• - Epidemiology.

• - Parasitology.

• - Statistical microbiology.

• - Health administration.

• - Industrial hygiene.

These are several of the activities in which Sanitary Engineering participates:

• - Water supply, treatment and distribution.

• - Sewage systems, treatment and control of black water (or sewage) and industrial waste.

• - Control of water pollution.

• - Municipal and rural garbage disposal services.

• - Control of rodents and insects.

• - Food hygiene.

• - Sanitation of schools, public places, summer resorts, swimming pools, etc.

• - Construction of hygienic homes.

• - Control of fumes, dusts, gases.

• - Industrial hygiene and sanitation.

• - Planning and urbanization of cities.

• - Civil engineering works, including the areas of hydraulics, structures, topography, geotechnics, foundations.

• - Chemical engineering work, including process and operations areas.

• - Mechanical engineering work, including the areas of design and operation of pumping equipment and equipment for different types of water treatment.

• - Electrical engineering work.

• - Laboratory analysis work") for the determination of physical and chemical parameters and the presence of organic matter.

• - Process and operations research studies.

• - Laboratory studies and work to analyze "bacteriological aspects").

• - Epidemiological studies and awareness-raising activities carried out by doctors specializing in public health.

• - Environmental studies carried out by specialists in environmental impact assessment.

• - Analysis and legal studies.

• - Economic and financial studies.

• - Marketing studies.

• - Social studies.

In the field of job opportunities, it is estimated that future graduates of the Sanitary Engineering program[1]​ will be in demand in the private and state sectors at the local, regional, national and international level.

In employment.com it is stated that the development of infrastructure for the energy, industrial and transportation sectors, the demand for professional services in the area of ​​engineering has increased. Although the Labor Observatory of the Ministry of National Education highlighted that the best occupational prospects are found in the basic cores of knowledge in administration, library science, economics, administrative engineering, mining engineering, electrical engineering, electronic engineering, systems engineering, mathematics and statistics, and medicine, all of these programs are related in their development to the generation of health and environmental problems.

Sanitary Engineering is a program of little dissemination among companies and needs to be consolidated and penetrate the market independently of Environmental Engineering. Sanitary Engineering is a career of the future, since all human activities generate sanitation problems that must be prevented, identified and solved. Internationally, in North America, the greatest demand occurs in the area of Engineering"), among which are earth sciences and focus on the field of life sciences, among others (Observatorio Laboral, 2010). In Argentina, engineering is a profession with excess labor demand. The Graduate Department determined that in 2006, among sixty (60) professionals interviewed, 99% were employed. It is also stated that they have many qualified job positions and an insufficient number of professionals or students to cover them (Universia, 2007).

A study by the Secretary of Economic Development of Bogotá, 2010, indicates that the activities that have the most demand in the capital are those related to transportation, technology and cosmetics, activities that must identify and avoid possible causes of environmental pollution (El Observatorio Nacional de la Universidad Colombiana, 2010). Job creation will be found in the next three or four years, in sectors such as cosmetics and hygiene products, textiles and clothing and agribusiness, forgetting that these activities need the development of health infrastructure and basic sanitation studies.

• - Tchobanoglous G. Sanitary Engineering - Sewer networks and wastewater pumping. Editorial Labor, S.A. 1985. ISBN 84 335 6422 6.

• - Michael Ray Overcash and Dhiraj Ray. Design of Land Treatment Systems For Industrial Wastes. Michigan: Ann Arborscience, 1979.

• - Cheremisinoff, N. P. and P. N. Cheremisinoff, Wafer Treatment and Waste Recovery: Advanced Technologies and Application, Prentice hall Publishers, New Jersey, 1993.

• - Sanitary and Gas Installations Civil Engineering Bahía Blanca Regional Faculty UTN 2005.

• - Sanitary Installations in buildings, 2nd edition, 1995 Enrique Jimeno Blasco.

• - Cold Water Systems, Drainage and Sanitary Facilities, F. Hall 1998,.

• - Hydraulic engineering.

• - Civil Engineering.

• - Environmental engineering.

• - Glossary of Health Promotion - WHO.

• - Sanitary Engineering Portal - Latin America.

• - Portal of Sanitary Engineering in Mexico - Mexico.

• - Colombian Association of Sanitary and Environmental Engineering - Acodal").

• - Univalle Sanitary Engineering - Univalle.

• - Sanitary Engineering University of Boyacá - Uniboyacá").