Integración de baterías en sistemas fotovoltaicos conectados a red

La situación actual del mercado energético en España y el imparable aumento de las tasas por parte de las eléctricas, está fomentando la búsqueda de fuentes de energía alternativas que permitan a la población poder abastecerse de electricidad, sin tener que pagar unos costes tan elevados. Para cubrir esta necesidad, la energía fotovoltaica y sobretodo el autoconsumo con inyección a red o balance neto, está adquiriendo cada vez más importancia dentro del mundo energético. Pero la penetración de esta tecnología en la Red Eléctrica Española tiene un freno, la desconfianza por parte del operador de la red, ya que la fotovoltaica es una fuente de energía intermitente, que puede introducir inestabilidades en el sistema en caso de alta penetración. Por ello se necesita ganar la confianza de las eléctricas, haciendo que sea una energía predecible, que aporte potencia a la red eléctrica cuando se le pida y que opere participando en la regulación de la frecuencia del sistema eléctrico. Para tal fin, el grupo de investigación de Sistemas Fotovoltaicos, perteneciente al IES de la UPM, está llevando a cabo un proyecto de investigación denominado PV CROPS, financiado por la Comisión Europea, y que tiene por objetivo desarrollar estas estrategias de gestión. En este contexto, el objetivo de este Proyecto Fin de Carrera consiste en implementar un Banco de Ensayos con Integración de Baterías en Sistemas FV Conectados a Red, que permita desarrollar, ensayar y validar estas estrategias. Aprovechando la disponibilidad para usar el Hogar Digital, instalado en la EUITT de la UPM, hemos montado el banco de ensayos en un laboratorio contiguo, y así, poder utilizar este Hogar como un caso real de consumos energéticos de una vivienda. Este banco de ensayos permitirá obtener información de la energía generada por la instalación fotovoltaica y del consumo real de la "casa" anexa, para desarrollar posteriormente estrategias de gestión de la electricidad. El Banco de Ensayos está compuesto por tres bloques principales, interconectados entre sí:  Subsistema de Captación de Datos y Comunicación. Encargado de monitorizar los elementos energéticos y de enviar la información recopilada al Subsistema de Control. Formado por analizadores de red eléctrica, monofásicos y de continua, y una pasarela orientada a la conversión del medio físico Ethernet a RS485.  Subsistema de Control. Punto de observación y recopilación de toda la información que proviene de los elementos energéticos. Es el subsistema donde se crearán y se implementarán estrategias de control energético. Compuesto por un equipo Pxie, controlador empotrado en un chasis de gama industrial, y un equipo PC Host, compuesto por una workstation y tres monitores.  Subsistema de Energía. Formado por los elementos que generan, controlan o consumen energía eléctrica, en el Banco de Ensayos. Constituido por una pérgola FV, un inversor, un inversor bidireccional y un bloque de baterías. El último paso ha sido llevar a cabo un Ejemplo de Aplicación Práctica, con el que hemos probado que el Banco de Ensayos está listo para usarse, es operativo y completamente funcional en operaciones de monitorización de generación energética fotovoltaica y consumo energético. ABSTRACT. The current situation of the energetic market in Spain and the unstoppable increase of the tax on the part of the electrical companies, is promoting the search of alternative sources of energy that allow to the population being able to be supplied of electricity, without having to pay so high costs. To meet this need, the photovoltaic power and above all the self-consumption with injection to network, it is increasingly important inside the energetic world. It allows to the individual not only to pay less for the electricity, in addition it allows to obtain benefits for the energy generated in his own home. But the penetration of this technology in the Electrical Spanish Network has an obstacle, the distrust on the part of the operator of the electrical network, due to the photovoltaic is an intermittent source of energy, which can introduce instabilities in the system in case of high penetration. Therefore it´s necessary to reach the confidence of the electricity companies, making it a predictable energy, which provides with power to the electrical network whenever necessary and that operates taking part in the regulation of the frequency of the electric system. For such an end, the group of system investigation Photovoltaic, belonging to the IES of the UPM, there is carrying out a project of investigation named PV CROPS, financed by the European Commission, and that has for aim to develop these strategies of management. In this context, the objective of this Senior Thesis consists in implementing a Bank of Tests with Integration of Batteries in Photovoltaic Systems Connected to Network, which allows developing, testing and validating these strategies. Taking advantage of the availability to use the Digital Home installed in the EUITT of the UPM, we have mounted the bank of tests in a contiguous laboratory to use this Home as a real case of energetic consumptions of a house. This bank of tests will allow obtaining information of the energy generated by the photovoltaic installation and information of the royal consumption of the attached "house", to develop later strategies of management of the electricity. The Bank of Tests is composed by three principal blocks, interconnected each other:  Subsystem of Gathering of data and Communication. In charge of monitoring the energetic elements and sending the information compiled to the Subsystem of Control. Formed by power analyzers, AC and DC, and a gateway for the conversion of the Ethernet physical medium to RS485.  Subsystem of Control. Point of observation and compilation of all the information that comes from the energetic elements. It is the subsystem where there will be created and there will be implemented strategies of energetic control. Composed of a Pxie, controller fixed in an industrial range chassis, and a PC Host, formed by a workstation and three monitors.  Subsystem of Energy. Formed by the elements of generating, controlling or consuming electric power, in the Bank of Tests. Made of photovoltaic modules, an inverter, a twoway inverter and a batteries block. The last step has been performing an Example of Practical Application we have proved that the Bank of Tests is ready to be used, it´s operative and fully functional in monitoring operations of energetic photovoltaic generation and energetic consumption.

Effect of five enological practices and of the general phenolic composition on fermentation-related aroma compounds in Mencia young red wines

The effects of five technological procedures and of the contents of total anthocyanins and condensed tan- nins on 19 fermentation-related aroma compounds of young red Mencia wines were studied. Multifactor ANOVA revealed that levels of those volatiles changed significantly over the length of storage in bottles and, to a lesser extent, due to other technological factors considered; total anthocyanins and condensed tannins also changed significantly as a result of the five practices assayed. Five aroma compounds pos- sessed an odour activity value >1 in all wines, and another four in some wines. Linear correlation among volatile compounds and general phenolic composition revealed that total anthocyanins were highly related to 14 different aroma compounds. Multifactor ANOVA, considering the content of total anthocy- anins as a sixth random factor, revealed that this parameter affected significantly the contents of ethyl lactate, ethyl isovalerate, 1-pentanol and ethyl octanoate. Thus, the aroma of young red Mencia wines may be affected by levels of total anthocyanins

Human resources policies for strategic csr. The experience of ree (Red Eléctrica de España)

Corporate Social Responsibility (CSR) strategies have a strong link with human resources policies. Not only because employees are one of the main stakeholders and because leaders’ style is directly related to the deployment of the strategy, but also, and with a growing importance, because a company culture aligned with CSR values could be a key competitive factor. The relationships among CSR values, employees’ commitment and productivity is one of the research lines of the GIOS (Grupo de Investigación de Organizaciones Sostenibles, Sustainable Organizations Research Group). Employees’ commitment management is one of the main challenges managers face, particularly in companies with a high proportion of knowledge workers. Many pieces of research indicate the direct relationship between employees’ commitment and company success. In this paper the results of a case study in REE (Red Eléctrica de España) identify some key variables to demonstrate that relationship. Based on commitment construct with the duality of emotional and rational commitment, and on the REE employee satisfaction survey, a direct relationship with organizational citizenship behaviour (OCB) variables appears. These OCB variables are an intermediate step with CSR values.From the results analysis of this survey a direct linear relationship can be seen between commitment and organizational citizenship behaviours. The relationships among emotional and rational commitment and OCB are examined separately with the conclusion being reached that there is a strong correlation in both cases. Moreover, the correlation between emotional commitment and OCB is somewhat stronger than that existing between rational commitment and OCB. it can also be seen how emotional commitment increases more strongly than rational commitment as organizational citizenship behaviours are gradually incorporated.

Planificación de una red 4G

La intensa evolución tecnológica que está experimentando nuestra sociedad en las últimas décadas hace que se estén desarrollando continuamente nuevas tecnologías que proporcionan mejoras tanto en la calidad como en la seguridad del servicio, este es el caso del 4G. A día de hoy, en España, la cuarta generación de comunicaciones móviles se ve encabezada por LTE, mientras que LTE-Advanced sólo se está implantando en las principales ciudades de nuestro país durante los últimos meses. Por este motivo, se ha creído interesante realizar una planificación sobre una zona que, hasta el momento, no está cubierta por cobertura LTE-Advanced. Además hay que tener en cuenta la naturaleza del terreno en el que trabajaremos, ya que se aleja del suelo urbano que encontramos en las principales ciudades con LTE-Advanced, como Madrid, Barcelona o Valencia. El estudio de esta zona semirural es de gran interés ya que uno de los objetivos de la cuarta generación es hacer llegar conexión a internet de calidad a lugares en los que no puede llegar la fibra óptica, como por ejemplo estas zonas semirurales. Para añadir aún más interés en el estudio, se ha decidido utilizar la banda de 800 MHz para el despliegue de la red. Esta banda que anteriormente era utilizada para la transmisión TDT, recientemente ha quedado liberada, en el conocido como Dividendo Digital para su uso en comunicaciones móviles. La tecnología LTE-Advanced se está empezando a desplegar en esta banda aunque realmente hasta Noviembre del año 2015 no tendremos un uso real de la misma, por lo que en estos momentos las redes 4G están utilizando la banda de 2.6 GHz. La utilización de la banda de 800 MHz conllevará mejoras tanto al usuario como a las operadoras, las cuales iremos viendo a lo largo del desarrollo del proyecto. La planificación pasará por distintas fases de optimización y expansión en las que se analizaran tanto la parte radioeléctrica como su capacidad. Se analizaran señales del tipo RSRP, RSSI o RSRQ y para el análisis de capacidad se definirá un conjunto de usuarios, distribuidos adecuadamente por toda la zona, que permitirá estudiar en detalle la capacidad de nuestra red. Para finalizar, se realizarán varias pruebas que demostrarán lo importante que es la tecnología MIMO tanto en LTE como en LTE-Advanced. ABSTRACT. Nowadays, our society is experiencing an intense pace of technological evolution which causes the constant development of new technologies. In the network planning area, these new technologies are focused on improving both quality and safety of service, with the recent deployment of 4G technologies in our networks. This project focuses on Spain, where the fourth generation of mobile communications is led by LTE, because LTE-Advanced has only been deployed in the largest cities, so far. The goal of this project is to plan, deploy and simulate LTE-Advanced network, of an area that hasn´t yet been covered. Furthermore, it will be taken into account the nature of the terrain where the network will be developed, as it moves away from urban areas in the major cities with LTE-Advanced, including Madrid, Barcelona and Valencia. The study of these semi-rural areas is extremely important because one of the main objectives of the fourth generation technologies is to get high-speed internet access to places that can be reached through other technologies, such as optical fiber. In order to adjust to the actual needs, the project was developed for the 800 MHz band. Those frequencies used to be assigned for digital terrestrial TV, but they have recently been released through the Digital Dividend in 2015 to use with mobile communications. That is the reason why, the LTE-Advanced technology in Spain is starting to be deployed in those frequencies. Despite the freeing of the 800 MHz band, it is not allowed to use it until November 2015, so 4G networks are currently using the 2.6 GHz band. The use of the 800 MHz band will led to advantages and improvements to users and operators, which will be detailed over the project. Each step of the planning of the 4G network is detailed. It is analyzed the optimization and expansion of the network, based on the radio and capacity premises. RSRP, RSSI or RSRQ signals were analyzed and an analysis of the network capacity was carried out. Finally, several tests are developed to show the importance of MIMO in LTE and LTE-Advanced.