Tu sólo, Todos juntos, Respuesta Inmediata a los Alumnos que es la tutoría

Los nuevos Planes de Estudios incluyen apartados sobre las Tutorías, generalmente encaminadas hacia la adjudicación de un grupo de alumnos a un profesor Tutor/Mentor durante toda su vida universitaria. Sobre el papel queda bien, pero puede haber profesores que lo consideren “una labor más”, con el consiguiente abandono o paso a un segundo plano de este difícil quehacer, que además requiere bastante tiempo y dedicación. Consideramos que la labor del TUTOR queda poco definida. Podemos apoyarnos en la bibliografía existente sobre las tutorías, pero ninguna responde a las necesidades globales por lo que sería una misión del Centro, o mejor aún de la Institución, quienes recojan y elaboren el material adecuado para las necesidades de nuestra Universidad. Si no se logra organizar la Acción Tutorial en conjunto, habrá profesores que intenten cumplirla, sintiéndose muy solos en ocasiones, y habrá profesores que “pasen” porque no la consideran una labor propiamente académica

New cementitious materials based on alkali-activated fly ash: performance at high temperatures

This paper reports on a comparative study of the mechanical performance at different temperatures of a commercial Portland cement, used as a control, and a new cementitious material made from an 8M-NaOH activated fly ash and containing no OPC. Two types of mechanical tests were conducted: (i) high temperature mechanical tests, to determine the strength and fracture toughness of the two materials between 251 and 6001C, and (ii) post-thermal treatment tests, to evaluate the residual strength after 1 h of exposure to different temperatures (2001, 4001, 6001, 8001, and 10001C). In both cases, the results showed that the new cementitious material performed significantly better at high temperatures than the Portland cement control. Differential thermogravimetry (DTG)/TG, Fourier transform infrared (FTIR), and X-ray diffraction analyses were also conducted to analyze the mineralogical and microstructural variations taking place in the material as a result of high temperature exposure. The results of these tests were correlated with the mechanical behaviour observed

Comportamiento mecánico a altas temperaturas de cementos de ceniza volante activados alcalinamente

En este trabajo se realiza un estudio comparativo del comportamiento mecánico, en función de la temperatura, entre un cemento Portland comercial, utilizado de referencia y dos nuevos materiales cementantes. Los ensayos realizados se han centrado en muestras de cemento portland , muestras de cenizas volantes activadas con un 100% de silicato sódico y muestras con un 70% de ceniza y un 30% de cemento activadas con un activador en estado sólido.Se realizaron dos tipos de ensayos: 1) post tratamiento térmico, donde se evaluó la resistencia mecánica residual tras una hora de exposición térmica a diferentes temperaturas, y 2) ensayos mecánicos a altas temperaturas , donde se determino el comportamiento mecánico y la tenacidad a la fractura a distintas temperaturas. Técnicas de Rayos X y microscopía electrónica de barrido han sido utilizadas para analizar las variaciones microestructurales en los materiales, como consecuencia de la exposición a altas temperaturas

Mechanical behavior of alkali-cement as function of the temperature.

This investigation reports on a comparative study of the mechanical behavior at different temperatures of three different alkali-activated fly ash pastes chemically activated using sodium silicate. A control Portland cement (OPC) was used as a reference. In an attempt to simulate the conditions prevailing in the event of accidental fire, post-thermal mechanical tests were performed to determine the residual strength. It has therefore been established that FA based cements can be fabricated for construction purposes and these materials have great potential for fire resistance applications

Surface modification of Al2O3–ZrO2(Y2O3) eutectic oxides by laser melting: processing and wear resistance

Surface coatings of pseudo-binary Al2O3–Zr2O3(Y2O3) eutectic oxides were produced by laser melting of the surface of conventionally sintered materials using a high-power diode laser. It was possible to obtain smooth, homogeneous, and crack-free coatings up to 50_7 mm2 in area by carefully controlling the processing conditions (laser power, traveling speed of the specimen, and substrate temperature). The surface treatment was aimed at creating a dense, wear-resistant coating based on the eutectic microstructure generated upon solidification. The microstructure of the coating was formed by elongated colonies, and was similar to that found in rods grown by the laser-heated floating zone method at the same growth rates. The laser-melted coating presented much higher hardness and wear resistance than the sintered materials, and the optimum mechanical properties were measured in samples treated at 500 mm/h with a laser line power of 65–80 W/cm. These samples presented a hardness and wear rate of 19.770.4 GPa and 3.8_10_6 mm3/N m, respectively, while those of the conventionally sintered materials were 14.37 0.2 GPa and 2.3_10_6 mm3/N m

Microstructural and mechanical study of AL2O3/Er3Al5O12 eutectic rods grown by the laser floating zone method

Eutectic rods of Al2O3–Er3Al5O12 were grown by directional solidification using the laser-heated floating zone method at rates in the range 25–1500 mm/h. Their microstructure and mechanical properties (hardness, toughness and strength) were investigated as a function of the growth rate. A homogeneous and interpenetrated microstructure was found in most cases, and interphase spacing decreased with growth rate following the Hunt–Jackson law. Hardness increased slightly as the interphase spacing decreased while toughness was low and independent of the microstructure. The rods presented very high bending strength as a result of the homogeneous microstructure, and their strength increased rapidly as the interphase spacing decreased, reaching a maximum of 2.7 GPa for the rods grown at 750 mm/h. The bending strength remained constant up to 1300 K and decreased above this temperature. The relationship between the microstructure and the mechanical properties was established from the analysis of the microstructure and of the fracture mechanism

Fracture Toughness and Strength of Al2O3-Y3Al5O12 and Al2O3-Y3Al5O12-ZrO2 Directionally-Solidified Eutetic Oxides up to 1900K

Ceramics rods of binary (Al2O3–Y3Al5O12) and ternary (Al2O3–Y3Al5O12–ZrO2) eutectic ceramic oxides were grown in air and nitrogen using the laser-heated floating zone method. Both materials presented a fine and homogeneous microstructure, free from defects, with an average interlamellar spacing of 1.1 and 0.7 _mfor the binary and ternary eutectics, respectively. The strength and the toughness of the rods were measured from ambient temperature up to 1900K by three-point bending. For the fracture tests, a sharp notch was introduced in the rods using a femto second-pulsed laser. Samples grown in nitrogen presented higher strength than those grown in air. The mechanical properties of the Al2O3–YAG binary eutectic did not change with a temperature up to 1500–1600K and plastic deformation above this temperature led to a slight reduction in strength and an increase in toughness. In the case of the ternary eutectic, the toughening effect of the thermal residual stresses disappeared at high temperature and the toughness decreased by a factor of two at 1473 K. The behavior of the ternary eutectic above this temperature followed the trends of the binary one although the changes in strength and toughness were much larger because of the smaller domain size (which favored diffusion-assisted plastic flow) and the lower eutectic temperature

Microestructura y propiedades mecánicas de fibras cerámicas eutécticas Al2O3/Er3Al5O12/ZrO2 procesadas por fusión zonal por láser.

Se han estudiado las fibras eutécticas Al2O3-Er3Al5O12-ZrO2 procesadas por fusión zonal por láser a distintas velocidades. Con el aumento de la velocidad de procesado se ha observado un refinamiento de la microestructura así como un cambio en la morfología de la misma. Se ha determinado mediante piezoespectroscopía que la fase alúmina se encuentra a compresión como consecuencia de las tensiones residuales que aparecen en la solidificación tras el fundido. El módulo de la componente hidrostática de dichas tensiones residuales se reduce conforme lo hace el tamaño de las fases. Se ha estudiado la dureza, la tenacidad de fractura y la resistencia a la flexión. Las dos primeras magnitudes han resultado independientes del tamaño de las fases, mientras que la resistencia a la flexión aumenta conforme disminuye el tamaño de las mismas. Finalmente, también se ha estudiado la dependencia de la resistencia a la flexión con la temperatura, observándose un comportamiento superplástico a 1700 K para la fibra procesada a mayor velocida

Mechanical behaviour at high temperature of alkali-activated aluminosilicates (geopolymers)

This study was designed to determine the effect of temperature on the mechanical strength (in both in vivo and post-exposure trials) of two alkaline cements (without OPC): (a) 100% fly ash (FA) and (b) 85% FA + 15% bauxite, the activated alkaline solution used was 85% 10-M NaOH + 15% sodium silicate. A Type I 42.5 R Portland cement was used as a control. Two series of trials were conducted: (i) in vivo trials in which bending and compressive strength, fracture toughness and modulus of elasticity were determined at different temperatures; and (ii) post-firing trials, assessing residual bending and compres-sive strength after a 1-h exposure to high temperatures and subsequent cooling. The findings showed that from 25 to 600 C, irrespective of the type of test (in vivo or post-firing), compressive mechanical strength rose, with the specimens exhibiting elastic behaviour and consequently brittle failure. At tem-peratures of over 600 C, behaviour differed depending on the type of test: (i) in the in vivo trials the high temperature induced pseudo-plastic strain and a decline in mechanical strength that did not necessarily entail specimen failure; (ii) in the post-firing trials, compressive strength rose

Comportamiento mecánico en función de la temperatura de aleaciones wolframio-vanadio.

En esta investigación se evalúa el comportamiento mecánico del wolframio puro y de dos de sus aleaciones con contenidos de 2% y 4% de vanadio, fabricadas mediante prensado isostático en caliente (HIP). La caracterización mecánica se ha realizado mediante ensayos de flexión en tres puntos en atmósfera oxidante a distintas temperaturas comprendidas entre temperatura ambiente y 1000 ºC. Adicionalmente, se han realizado ensayos en inmersión en nitrógeno líquido para los de -197 ºC. Estos últimos valores pueden servir para una determinación más precisa de la temperatura la transición dúctil-frágil en éstos materiales, y de su posible comportamiento plástico o frágil a temperatura ambiente. Mediante estos ensayos ha sido posible obtener la tenacidad de fractura, la resistencia mecánica, el límite elástico y el módulo de elasticidad en función de la temperatura. Así mismo, se ha determinado la densidad y la dureza Vickers para dos cargas distintas, lo que permitido determinar la influencia de este parámetro en la medida realizada. Adicionalmente, se han examinado mediante microscopia electrónica de barrido las superficies de fractura. De esta forma ha sido posible determinar el modo de rotura y analizar la relación de las propiedades mecánicas macroscópicas con los micromecanismos de fallo involucrados