摘要:
When transferring an adhesion layer 28 to an electrode layer 12a, carrier sheets 20 and 26 are fed between first and second transfer rolls 40 and 42 so that a rear surface of a first carrier sheet 20, in which the electrode layer is formed, makes contact with a first transfer roll 40 and a rear surface of a second carrier sheet 26, in which adhesion layer 28 is formed, makes contact with a second transfer roll 42; and a first transfer roll 40 is heated at a first predetermined temperature T1 (° C.), a second transfer roll 42 is heated at a second predetermined temperature T2 (° C.), in which a first predetermined temperature T1 and a second predetermined temperature T2 satisfy 60
摘要:
A printing and drying method comprising laying a support sheet 20 elongated in the long direction so as to bridge both a printing zone 42 and a drying zone 44, in the printing zone 42, giving the support sheet 20 a first tension F1, in that state, printing the support sheet 20 with predetermined patterns, then feeding the support sheet 20 toward the drying zone 44, in the drying zone 44, giving the support sheet 20 on which the predetermined patterns were printed a second tension F2, and in that state, drying it in a drying chamber 62. The first tension F1 and the second tension F2 are given by separate tension giving means, and the second tension F2 is tension given along the support sheet 20 in the long direction and able to prevent shrinkage of the support sheet 20 in the long direction while passing through the drying zone 44.
摘要:
A printing and drying method comprising laying a support sheet 20 elongated in the long direction so as to bridge both a printing zone 42 and a drying zone 44, in the printing zone 42, giving the support sheet 20 a first tension F1, in that state, printing the support sheet 20 with predetermined patterns, then feeding the support sheet 20 toward the drying zone 44, in the drying zone 44, giving the support sheet 20 on which the predetermined patterns were printed a second tension F2, and in that state, drying it in a drying chamber 62. The first tension F1 and the second tension F2 are given by separate tension giving means, and the second tension F2 is tension given along the support sheet 20 in the long direction and able to prevent shrinkage of the support sheet 20 in the long direction while passing through the drying zone 44.
摘要:
A main object of the present invention is to provide an anode active material capable of increasing energy density at the same time increasing battery safety, and a metal ion battery prepared with the anode active material. The present invention is an anode active material including an element that belongs to alunite group capable to insert and remove an ion(s) of at least one metal element selected from the group consisting of alkali metal elements and alkaline-earth metal elements, and a metal ion battery having a cathode, an anode, and an electrolyte filled between the cathode and the anode, the electrolyte conducting a metal ion(s), wherein the anode active material is contained in the anode.
摘要:
The main object of the present invention is to provide a cathode active material capable of reducing the initial interface resistance against a solid electrolyte material. The present invention solves the above-mentioned problems by providing a cathode active material comprising a cathode active substance exhibiting strong basicity and a coat layer formed so as to cover the surface of the above-mentioned cathode active substance and provided with a polyanionic structural part exhibiting acidity.
摘要:
A main object of the present invention is to provide an anode active material capable of increasing energy density at the same time increasing battery safety, and a metal ion battery prepared with the anode active material. The present invention is an anode active material including an element that belongs to alunite group capable to insert and remove an ion(s) of at least one metal element selected from the group consisting of alkali metal elements and alkaline-earth metal elements, and a metal ion battery having a cathode, an anode, and an electrolyte filled between the cathode and the anode, the electrolyte conducting a metal ion(s), wherein the anode active material is contained in the anode.
摘要:
An object of the present invention is to provide a high-capacity, low cycle deterioration lithium secondary battery in which the positive electrode is provided with a titanium composite oxide such as Li2NiTiO4. A lithium secondary battery 100 provided by the present invention includes a positive electrode 10 and a negative electrode 20. The positive electrode 10 has a solid solution between Li2M1TiO4 (where M1 is at least one metal element selected from the group consisting of Mn, Fe, Co, and Ni) and LiM2O2 (where M2 is at least one metal element selected from the group consisting of Mn, Co, and Ni).
摘要翻译:本发明的目的是提供一种高容量,低循环劣化的锂二次电池,其中正极设置有诸如Li 2 NiTiO 4的钛复合氧化物。 本发明提供的锂二次电池100包括正极10和负极20.正极10具有Li 2 M 1 TiO 4之间的固溶体(其中,M1为选自Mn,Fe, Co和Ni)和LiM 2 O 2(其中M2是选自Mn,Co和Ni中的至少一种金属元素)。
摘要:
An electronic device having an element body comprising an internal electrode layer, wherein the internal electrode layer includes an alloy, the alloy contains a nickel (Ni) element and at least one kind of element selected from ruthenium (Ru), rhodium (Rh), rhenium (Re) and platinum (Pt), and a content of each component is Ni: 80 to 100 mol % (note that 100 mol % is excluded) and a total of Ru, Rh, Re and Pt: 0 to 20 mol % (note that 0 mol % is excluded).
摘要:
A production method of a multilayer electronic device, comprising the steps of forming a lower side green sheet 10a including at least a ceramic powder on a supporting body 20; forming an electrode pattern layer 12a on a surface of the lower side green sheet; forming a green chip by stacking multilayer units U1 including at least the lower side green sheet and an electrode pattern layer; and firing the green chip; wherein the lower side green sheet 10a formed on the supporting body 20 includes a binder of a curable resin, and the curable resin in the lower side green sheet 10a is cured before forming said electrode pattern layer 12a on the lower side green sheet.
摘要:
It is an object of the present invention is to provide a method for manufacturing a multi-layered unit for a multi-layered ceramic electronic component which can prevent a ceramic green sheet from being deformed and destroyed and prevent a solvent contained in an electrode paste from sinking into a ceramic green sheet, thereby enabling manufacture of a multi-layered unit including a ceramic green sheet and an electrode layer laminated to each other in a desired manner. The method for manufacturing a multi-layered unit for a multi-layered ceramic electronic component according to the present invention includes a step of forming a ceramic green sheet on the surface of a first carrier film, a step of forming a release layer on the surface of a second carrier film including a surface-treated region on which a surface treatment is performed for improving releasability and non-surface-treated regions on which no surface treatment is performed on both sides of the surface-treated region and having a width substantially equal to that of the first carrier film, a step of forming an electrode layer in a predetermined pattern and a spacer layer in a complementary pattern to that of the electrode layer on the surface of the release layer, thereby forming an inner electrode layer, a step of forming an adhesive layer on the surface of a third carrier film having a width substantially equal to that of the second carrier film, a step of transferring the adhesive layer formed on the third carrier film onto the surface of the inner electrode layer, and a step of transferring the ceramic green sheet formed on the surface of the first carrier film onto the adhesive layer transferred on the surface of the inner electrode layer formed on the surface of the second carrier film, thereby fabricating a multi-layered unit including the ceramic green sheet and the inner electrode layer laminated onto each other, wherein the adhesive layer is formed by coating the surface of the third carrier film with an adhesive agent solution so that the width of the adhesive layer is narrower than the width of the third carrier film by at least 2α where α is a positive value, wider than the width of the ceramic green sheet formed on the surface of the first carrier film and the widths of the release layer and the inner electrode layer formed on the surface of the second carrier film by at least 2α and wider than the width of the surface-treated region of the second carrier film by at least 2α.