Abstract: A subtitle display processing device, a server, and a non-transitory tangible storage medium that stores a program are provided. The subtitle display processing device includes: a data outputter configured to output text data; a display setter configured to set a display position and a display size of a text display area; an indicator configured to display the text data in the text display area; and a changer configured to change at least one of the display position and the display size of the text display area in accordance with a preset change condition.

Abstract: Disclosed herein is an apparatus that includes a plurality of cell capacitors arranged in a memory cell array region of a semiconductor substrate, each of the plurality of cell capacitors having a first electrode, a second electrode and an insulating film therebetween to electrically disconnect the first and second electrodes, a first conductive member including the plurality of cell capacitors therein, the first conductive member being electrically connected in common to the first electrodes of the plurality of cell capacitors, and a second conductive member formed on an upper surface of the first conductive member, a material of the second conductive member being different from that of the first conductive member. A side surface of the first conductive member is free from the second conductive member.

Abstract: A subtitle display processing device, a server, and a non-transitory tangible storage medium that stores a program are provided. The subtitle display processing device includes: a data outputter configured to output text data; a display setter configured to set a display position and a display size of a text display area; an indicator configured to display the text data in the text display area; and a changer configured to change at least one of the display position and the display size of the text display area in accordance with a preset change condition.

Abstract: A gas sensor includes a sensor element, an inner protective cover having one or more element chamber inlets and including a first member and a second member, and an outer protective cover having one or more outer inlets. A first gas chamber between the outer protective cover and the inner protective cover has a first space and a second space. A cross-sectional area Cs that is a flow channel cross-sectional area in the second space when the measurement-object gas passes from an outside of the second member toward an inside of the second member just above the second member is greater than or equal to 14.0 mm2, and a cross-sectional area Ds that is a cross-sectional area perpendicular to a circumferential direction of the inner protective cover in the second space is greater than or equal to 0.5 mm2 and less than or equal to 6.4 mm2.

Abstract: A gas sensor includes a sensor element, an inner protective cover having inside a sensor element chamber and having an element chamber inlet and an element chamber outlet, and an outer protective cover having an outer inlet and an outer outlet. A total cross-sectional area A [mm2] of the outer inlet, a total cross-sectional area B [mm2] of the element chamber inlet, a total cross-sectional area C [mm2] of the element chamber outlet, and a total cross-sectional area D [mm2] of the outer outlet satisfy B>A>C>D, a cross-sectional area ratio A/D is greater than a value of 2.0 and less than or equal to a value of 5.0, and A×B×C×D is greater than or equal to a value of 3000 and less than or equal to a value of 8500.

Abstract: A gas sensor includes a sensor element, an inner protective cover having one or more element chamber inlets and including a first member and a second member, and an outer protective cover having one or more outer inlets. A first gas chamber between the outer protective cover and the inner protective cover has a first space and a second space. A cross-sectional area Cs that is a flow channel cross-sectional area in the second space when the measurement-object gas passes from an outside of the second member toward an inside of the second member just above the second member is greater than or equal to 14.0 mm2, and a cross-sectional area Ds that is a cross-sectional area perpendicular to a circumferential direction of the inner protective cover in the second space is greater than or equal to 0.5 mm2 and less than or equal to 6.4 mm2.

Abstract: A gas sensor includes a sensor element, an inner protective cover having inside a sensor element chamber and having an element chamber inlet and an element chamber outlet, and an outer protective cover having an outer inlet and an outer outlet. A total cross-sectional area A [mm2] of the outer inlet, a total cross-sectional area B [mm2] of the element chamber inlet, a total cross-sectional area C [mm2] of the element chamber outlet, and a total cross-sectional area D [mm2] of the outer outlet satisfy B>A>C>D, a cross-sectional area ratio A/D is greater than a value of 2.0 and less than or equal to a value of 5.0, and A×B×C×D is greater than or equal to a value of 3000 and less than or equal to a value of 8500.

Abstract: In a gas sensor, a powder compact seals a void space between an inner peripheral surface of metal-made main hardware and a sensor element, and the inner peripheral surface has arithmetic average roughness of 0.5 to 5 ?m. The gas sensor includes supporters, which are arranged in a penetration hole of the main hardware, which allow the sensor element to penetrate therethrough, and which press the powder compact in sandwiching relation from both sides in an axial direction. A surface of at least one of the supporters has the arithmetic average roughness of not more than 0.5 ?m.

Abstract: A method of measuring adhesive strength between an element body and a porous protection layer that are included in a sensor element includes (a) a step of holding a portion of the element body where the porous protection layer is absent with an elastic force exerted by a holding jig, and placing a peeling jig at a position between the porous protection layer and the holding jig in the longitudinal direction such that the element body is allowed to move in the longitudinal direction while the porous protection layer is prevented from moving in the longitudinal direction toward the holding jig; and (b) a step of moving, after the step (a), the peeling jig pushes the porous protection layer in the longitudinal direction, and measuring the adhesive strength of the porous protection layer.

Abstract: An inner protective cover 130 of a gas sensor forms an element-chamber inlet 127 having a first outside opening 128a, a second outside opening 128b, and an element-side opening 129. The second outside opening 128b is disposed such that the path of a measurement-object gas from the first outside opening 128a to the element-side opening 129 of the element-chamber inlet 127 communicates in the middle thereof with a first gas chamber 122, and that there is a path shorter than the shortest path of the measurement-object gas extending from an outer inlet 144a through the first outside opening 128a to a gas inlet 111.

Abstract: A method of measuring adhesive strength between an element body and a porous protection layer that are included in a sensor element includes (a) a step of holding a portion of the element body where the porous protection layer is absent with an elastic force exerted by a holding jig, and placing a peeling jig at a position between the porous protection layer and the holding jig in the longitudinal direction such that the element body is allowed to move in the longitudinal direction while the porous protection layer is prevented from moving in the longitudinal direction toward the holding jig; and (b) a step of moving, after the step (a), the peeling jig pushes the porous protection layer in the longitudinal direction, and measuring the adhesive strength of the porous protection layer.

Abstract: A gas sensor 100 includes a sensor element 110 having a gas inlet 111; an inner protective cover 130 which has a sensor element chamber 124 thereinside and in which an element-chamber inlet 127 and an element-chamber outlet 138a are arranged; and an outer protective cover 140 including a body portion 143, which has a cylindrical shape and in which an outer inlet 144a is arranged, and a front end portion 146, which has an inner diameter smaller than that of the body portion 143 and in which an outer outlet 147a is arranged. The outer inlet 144a includes a horizontal hole 144b arranged in a side portion 143a of the body portion 143 of the outer protective cover 140. The outer outlet 147a is not arranged in a side portion 146a of the front end portion 146 of the outer protective cover 140.

Abstract: An inner protective cover 130 of a gas sensor forms an element-chamber inlet 127 having a first outside opening 128a, a second outside opening 128b, and an element-side opening 129. The second outside opening 128b is disposed such that the path of a measurement-object gas from the first outside opening 128a to the element-side opening 129 of the element-chamber inlet 127 communicates in the middle thereof with a first gas chamber 122, and that there is a path shorter than the shortest path of the measurement-object gas extending from an outer inlet 144a through the first outside opening 128a to a gas inlet 111.

Abstract: A gas sensor 100 includes a sensor element 110 having a gas inlet 111; an inner protective cover 130 which has a sensor element chamber 124 thereinside and in which at least one element-chamber inlet 127 and at least one element-chamber outlet are arranged; and an outer protective cover 140 in which at least one outer inlet 144a and at least one outer outlet are arranged. A minimum path length P from the outer inlet 144a to the gas inlet 111 is 5.0 mm or more and 11.0 mm or less.

Abstract: A gas sensor 100 includes a sensor element 110 having a gas inlet 111; an inner protective cover 130 which has a sensor element chamber 124 thereinside and in which at least one element-chamber inlet 127 and at least one element-chamber outlet 138a are arranged; and an outer protective cover 140 in which at least one outer inlet 144a and at least one outer outlet 147a are arranged. A cross-sectional area ratio S1/S2, which is a ratio of a total cross-sectional area S1 [mm2] of the outer inlet 144a to a total cross-sectional area S2 [mm2] of the outer outlet 147a, is more than 2.0 and 5.0 or less.

Abstract: In a gas sensor 10, a powder compact 45a seals a void space between an inner peripheral surface 42c of metal-made main hardware 42 and a sensor element 20, and the inner peripheral surface 42c has arithmetic average roughness Ra of 0.5 to 5 ?m. The gas sensor 10 includes supporters 44a and 44b, which are arranged in a penetration hole of the main hardware 42, which allow the sensor element 20 to penetrate therethrough, and which press the powder compact 45a in sandwiching relation from both sides in an axial direction. A surface of at least one of the supporters 44a and 44b has the arithmetic average roughness Ra of not more than 0.5 ?m.

Abstract: In a gas sensor, a powder compact seals a void space between an inner peripheral surface of metal-made main hardware and a sensor element, and the inner peripheral surface has arithmetic average roughness of 0.5 to 5 ?m. The gas sensor includes supporters, which are arranged in a penetration hole of the main hardware, which allow the sensor element to penetrate therethrough, and which press the powder compact in sandwiching relation from both sides in an axial direction. A surface of at least one of the supporters has the arithmetic average roughness of not more than 0.5 ?m.