18 research outputs found

    Amélioration du comportement électrochimique des batteries plomb-acide à usage photovoltaïque

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    Texte intégral accessible uniquement aux membres de l'Université de LorraineIn an isolated photovoltaic system, the accumulator is the weak point of the device. His charge capacity is closely related to the conduction properties of the grid/PAM interface, interface which evolves according to the state of charge. The positives grids, made with a Pb-Ca-Sn alloy, play the role of both collector of current and support of the positive active mass. At ambient temperature, these alloys are prone to metallurgical transformation, which is followed by a drop of the mechanical properties and by a reduction of the corrosion resistance whatever the charge conditions are. The use of a heat treatment makes it possible to durably maintain alloy in the state in which the best behaviors are observed. The addition of tin in the alloy, associated to the heat treatment, allows to improve the properties of material more. Moreover the tin, like silver and rare earth, plays an essential role in the formation and the growth of the lead oxides, but on the properties of adherence of the corrosion layer during the tests of cycling too.Dans un système photovoltaïque, la batterie est le point faible de l'installation. Sa capacité de recharge est liée aux propriétés de conduction de l'interface grille/MA positive, interface qui évolue en fonction de l'état de charge. Les grilles positives sont en alliages Pb-Ca-Sn et ont le double rôle de collecteur de courant et de support de la MA. A température ambiante, ces alliages sont sujets à des changements d'états métallurgiques qui s'accompagne d'une chute des propriétés mécaniques et d'une diminution de la résistance à la corrosion quelque soit les conditions de charges rencontrées. L'application d'un traitement thermique permet de maintenir durablement l'alliage dans l'état garant des meilleurs comportements. L'ajout d'étain à l'alliage, associé à un traitement thermique, permet d'améliorer encore les propriétés mécaniques du matériau. Par ailleurs, l'étain, comme l'argent, le lanthane et le cérium, influence la formation et la croissance des oxydes de plomb mais aussi l'adhérence de la couche de corrosion dans des conditions de cyclage

    Amélioration du comportement électrochimique des batteries plomb-acide à usage photovoltaïque

    No full text
    Dans un système photovoltaïque, la batterie est le point faible de l'installation. Sa capacité de recharge est liée aux propriétés de conduction de l'interface grille/MA positive, interface qui évolue en fonction de l'état de charge. Les grilles positives sont en alliages PbCaSn et ont le double rôle de collecteur de courant et de support de la MA. A température ambiante, ces alliages sont sujets à des changements d'états métallurgiques qui s'accompagne d'une chute des propriétés mécaniques et d'une diminution de la résistance à la corrosion quelque soit les conditions de charges rencontrées. L'application d'un traitement thermique permet de maintenir durablement l'alliage dans l'état garant des meilleurs comportements. L'ajout d'étain à l'alliage, associé à un traitement thermique, permet d'améliorer encore les propriétés mécaniques du matériau. Par ailleurs, l'étain, comme l'argent, le lanthane et le cérium, influence la formation et la croissance des oxydes de plomb mais aussi l'adhérence de la couche de corrosion dans des conditions de cyclage.In an isolated photovoltaic system, the accumulator is the weak point of the device. His charge capacity is closely related to the conduction properties of the grid/PAM interface, interface which evolves according to the state of charge. The positives grids, made with a PbCaSn alloy, play the role of both collector of current and support of the positive active mass. At ambient temperature, these alloys are prone to metallurgical transformation, which is followed by a drop of the mechanical properties and by a reduction of the corrosion resistance whatever the charge conditions are. The use of a heat treatment makes it possible to durably maintain alloy in the state in which the best behaviors are observed. The addition of tin in the alloy, associated to the heat treatment, allows to improve the properties of material more. Moreover the tin, like silver and rare earth, plays an essential role in the formation and the growth of the lead oxides, but on the properties of adherence of the corrosion layer during the tests of cycling too.NANCY1-SCD Sciences & Techniques (545782101) / SudocSudocFranceF

    Microwave-assisted reactive sintering and lithium ion conductivity of Li 1.3 Al 0.3 Ti 1.7 (PO 4 ) 3 solid electrolyte

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    International audienceLi1.3Al0.3Ti1.7(PO4)3 (LATP) materials are made of a three−dimensional framework of TiO6 octahedra and PO4 tetrahedra, which provides several positions for Li+ ions. The resulting high ionic conductivity is promising to yield electrolytes for all-solid-state Li-ion batteries. In order to elaborate dense ceramics, conventional sintering methods often use high temperature (≥1000 °C) with long dwelling times (several hours) to achieve high relative density (∼90%). In this work, an innovative synthesis and processing approach is proposed. A fast and easy processing technique called microwave-assisted reactive sintering is used to both synthesize and sinter LATP ceramics with suitable properties in one single step. Pure and crystalline LATP ceramics can be achieved in only 10 min at 890 °C starting from amorphous, compacted LATP's precursors powders. Despite a relative density of 88%, the ionic conductivity measured at ambient temperature (3.15 × 10−4 S cm−1) is among the best reported so far. The study of the activation energy for Li+ conduction confirms the high quality of the ceramic (purity and crystallinity) achieved by using this new approach, thus emphasizing its interest for making ion-conducting ceramics in a simple and fast way

    Elaboration and characterization of a free standing LiSICON membrane for aqueous lithium-air battery

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    In order to develop a LISICON separator for an aqueouslithium-airbattery, a thin membrane was prepared by a tape-casting of a Li1.3Al0.3Ti1.7 (PO4)3-AlPO4 based slip followed by a sintering step. By optimizing the grain sizes, the slip composition and the sintering treatment, the mechanical properties were improved and the membrane was reduced to a thickness of down to 40 μm. As a result, the ionic resistance is relatively low, around 38 Ω for a 55 μm membrane of 1 cm2. One side of the membrane was coated with alithium oxynitrured phosphorous (LiPON) thin film to prevent lithium metal attack. Lithium metal was electrochemically deposited on the LiPON surface from a saturated aqueous solution of LiOH. However, the ionic resistance of the LiPON film, around 67 Ω for a 1.2 μm film of 1 cm2, still causes an important ohmic loss contribution which limits the power performance of a lithium-air battery

    Critical Current Density Limitation of LLZO Solid Electrolyte: Microstructure vs Interface

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    International audienceAl-doped Li 7 La 3 Zr 2 O 12 (LLZO) solid electrolyte is a promising candidate for all-solid-state lithium battery (ASSB) due to its high ionic conductivity and stability against lithium metal. Dense LLZO pellets were prepared by high-temperature sintering and a Li 3 BO 3 melting agent was used to control the microstructure (grain size and grain boundary chemistry). An ionic conductivity of 0.49 mS·cm −1 was measured at room temperature. The LLZO/Li interface was modified by introducing an aluminum layer. The impact of the microstructure of LLZO ceramics and the chemistry of the LLZO/Li interface were discussed by measuring the critical current density (CCD). Even though secondary phases at the grain boundary lead to an increase of the electronic conductivity, no significant influence of the microstructure on the CCD value (50 μ A·cm −2 ) has been established. The low CCD value has been improved by forming an Al-Li alloy interlayer at the LLZO/Li interface, due to a better homogenization of the Li current at the interface. In parallel, the applied pressure (0.09 MPa vs. 0.4 MPa) has been studied and did impact the CCD. A value of 0.35 μ A·cm −2 was measured. These results highlight the conditions needed for keeping a good electrolyte/Li interface during the cycling of a solid state battery

    Effect of electrolyte flow on a gas evolution electrode

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    International audienceIn this study, the effect of flow of the electrolyte on an electrolysis cell and a zinc cell is investigated. The gain of energy brought by the flow is discussed and compared to the viscous losses in the cells. We point out that the balance between the gained electrical power and the viscous loss power is positive only if the hydrodynamic resistance of the circuit is correctly designed and further comment on the economical viability of the whole process. A model of the studied phenomena is proposed in the last section. This analytical model captures the dynamics of the process, gives the optimal flowing conditions and the limits of the energetical rentability of the process. This study shows that the use of flowing electrolyte in zinc-air batteries can be energetically profitable with the appropriate flowing conditions
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