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Nicaragua

Nicaragua Solar Thermal

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Undoubtedly, the emblematic project, in terms of thermal solar energy, is the system inaugurated on October 9, 2018 at the Doctor Alejandro Dávila Bolaños Military Hospital in Managua.

With an investment of US $ 4.3 million financed through a soft loan from Oesterreichische Kontrollbank and Raiffeisen Bank International and with the United Nations Agency for Industrial Development (UNIDO), and the National Production Center more Clean from Nicaragua support; This system provides 30% of the demand required for air conditioning and 100% of the demand for hot water (used in various hospital operational functions, such as: personal, patients and doctors hygiene, food cleaning and preparation in the kitchen, for laundry area, among others).

The solar system was installed in a 4,450 square meters area, is composed of 338 thermal solar panels and will have an environment positive impact eliminating more than 1,100 tons of dioxide carbon emission each year.

It is the second largest system in the world, the largest in hospitals and unique in Latin America.

Resultado de imagen de energía solar hospital militar nicaragua

Despite the increase in systems number, solar energy only represents 1% of Nicaragua’s energy matrix.

There is a feeling that decision making is more market focused and not as a development issue.

The key is to associate the solar technology development with economic activities, establish a relationship between water resources, renewable energy and food security and base on renewable energy the climate change adaptation.

Currently solar energy provides energy security in contrast, for example, to energy supply via hydroelectric dams that depends on rains that are varying more and more throughout the region due to climate change.

Resultado de imagen de energía solar térmica nicaragua

Energy sources diversification becomes indispensable and has led to a solar energy investments growth.

This has been possible due to public resources contribution to support this technology development, the political commitment and the role carried out by the private initiative.

In this sense, it is worth highlighting the work that the BID is doing in the region.

In spite of advances, the pending subject continues being the regional energetic integration.

An energy networks extension at regional level would help lower costs and a energy supply diversification would guarantee greater energy security.

All you need is Sun. All you need is Sopelia.

Solar Thermal Energy

Heat Transfer Fluid

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Heat transfer fluid passes through absorber and transfers energy to thermal utilization system (accumulator or exchanger).

Most used types are:

* Natural water: can be used in open circuit, when sanitary water passes directly through collectors, or in closed circuit (independent consumption circuit).

In first case, circuit can only be constituted by materials allowed for drinking water supply. In some countries this system is not allowed.

It will be necessary to consider water characteristics, especially its hardness (calcium and magnesium amount), which when heated produces a hard crust or tartar.

This crust accelerates corrosion, restricts flow and reduces heat transfer. The values start to be problematic from 60 mg / l. Very soft waters can also cause problems due to their corrosivity.

* Water with antifreeze: to avoid drawbacks of freezing and boiling of heat transfer fluid, use of antifreezes called “glycols” is the most widespread.

Mixed with water in certain proportions prevent freezing to a limit of temperatures below 0 ° C depending on their concentration.

On the other hand the boiling point rises making heat transfer is protected against too high temperatures.

Choice of concentration will depend on historical temperatures of the area where installation is located and on characteristics provided by manufacturer.

Most commonly used glycols are ethylene glycol and propylene glicol.

Resultado de imagen de tabla anticongelante solar

Fundamental characteristics of antifreeze:

• They are toxic: their mixing with drinking water must be prevented by making secondary circuit pressure greater than that of primary, for prevention exchanger possible breakage.

• They are very viscous: factor to take into account when choosing electric pump that is usually more powerful.

• Dilates more than water when heated: as a safety standard, when we use antifreeze in proportions of up to 30%, when sizing the expansion vessel, we will apply a coefficient of 1.1 and 1.2 if proportion is greater.

• It is unstable at more than 120ºC: it loses its properties so it stops avoiding freezing. There are some that withstand higher temperatures, but they are expensive.

• The boiling temperature is higher than that of water alone, but not too much.

• Specific heat is lower than that of water alone, so it must be taken into account in the flow calculation, conditioning pipe and pump dimensioning.

To calculate antifreeze amount that must be added to an installation, you must first consult the table of historical temperatures which is the minimum temperature recorded in that city or location.

Once it is known, goes to glycols graph supplied by manufacturer and value is transferred to indicate what percentage is.

* Organics fluids: there are two types, synthetic and petroleum derivatives.
Precautions mentioned in case of antifreeze regarding toxicity, viscosity and dilation are applicable to organic fluids. Additional risk of fire should be mentioned, but also that they are chemically stable at elevated temperatures.

* Silicone oils: they are stable and of good quality products. They have the advantages that they are not toxic and that they are not flammable, but current high prices mean they are not widely used.

All you need is Sun. All you need is Sopelia.

Solar Thermal Energy

Solar Thermal Latin America

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Solar thermal energy for domestic applications is a mature technology that has been successfully developed in many countries for over 30 years.

It is not well understood why its underdeveloped compared with photovoltaics while almost double its performance.

It is a relatively simple technology that already has small and medium manufacturers in countries of the region such as Argentina, Uruguay and Brazil. However, there is still no certification at regional level as in Europe.

In the Caribbean nation of Barbados 80% – 90% of households have solar energy equipment on their roofs. This country ranks in the top 5 global installed capacity per capita.

There are no reliable data concerning the installed capacity in Latin America.

The most recent global estimate dating from 2012 and informs an installed capacity of 234 GWth. Brazil is among the top 7 countries with about 4 GWth (2%).

The Latin American regional market is slowly developing.

In parallel, there is an emerging incipient regulatory framework for certifications that are mainly based on regulatory frameworks of Europe and the US. COPANT is working on the unification of the regional framework of standards and certifications.

One of the main barriers to the development of solar thermal energy are important subsidies that some countries in the region granted to conventional energy.

Professionals and companies in the solar energy industry of Latin America and the Caribbean met recently in San Jose, Costa Rica, to promote the development of this technology in the region.

The meeting was made by IRENA (International Renewable Energy Agency), OLADE (Latin American Energy Organization), ICE (Instituto Costarricense de Electricidad) and the German Metrology Institute (PTB).

According to the Innovation and Technology Department of IRENA, currently the region only takes advantage of 3% of its solar thermal potential.

The most important conclusión we arrived is that the region has great potential for development of solar energy in residential and commercial areas, but experience shows that to achieve this, we must build confidence in this technology.

How is this achieved ?

Proposals were:

1) Develop mechanisms to ensure the quality of the facilities (standards and inspections)

2) Encourage best practices among professionals and companies (testing and certification)

3) Implement government policies that promote genuine development of this technology

The global analysis of the development programs of solar thermal energy estimates a worldwide installed capacity of 1,600 GWth in 2030 and 3,500 in 2050 GWth.

Will be Latin America an important player in this global installed capacity growing ?

To know that, in next deliveries we will discuss solar thermal sector of each country in the region.