Abstract: A control device includes a trained model for receiving a feature amount calculated from information collected from the control target to output a score, and a threshold value for determining the score An information processing device displays a feature amount related to the trained model and a score calculated from the feature amount, receives setting of a threshold value for any of the feature amount and the score, calculates a threshold value for the score from the threshold value set for the feature amount, and outputs, as a threshold value to be applied to the trained model, any of the threshold value set for the score and the threshold value for the score calculated from the threshold value set for the feature amount.

Abstract: A vertical layer stack including a bit-line-level dielectric layer and an etch stop dielectric layer can be formed over an array region. Bit-line trenches are formed through the vertical layer stack. Bit-line-trench fill structures are formed in the bit-line trenches. Each of the bit-line-trench fill structures includes a stack of a bit line and a capping dielectric strip. At least one via-level dielectric layer can be formed over the vertical layer stack. A bit-line-contact via cavity can be formed through the at least one via-level dielectric layer and one of the capping dielectric strips. A bit-line-contact via structure formed in the bit-line-contact via cavity includes a stepped bottom surface including a top surface of one of the bit lines, a sidewall segment of the etch stop dielectric layer, and a segment of a top surface of the etch stop dielectric layer.

Abstract: A holding frame holds a polygonal solar battery panel including a light receiving surface. The frame includes a lower disposed in a spaced relationship with a back surface opposite to the light receiving surface, a rising part extending upward from the lower part, and a holding part formed at an end portion of the rising part on a side of the panel to hold one side of the panel. The holding part includes a portion protruding inwardly from the end portion, a portion protruding outwardly from the end portion, a portion extending upwardly from an outside of the outward-protruding portion, and a sandwiching portion extending inwardly from the upward extending portion to sandwich the panel between the sandwiching portion and the outward-protruding portion. The lower part includes a portion protruding inwardly relative to the rising part, and an outward-protruding portion protruding outwardly relative to the rising part.

Abstract: A holding frame holds a polygonal solar battery panel including a light receiving surface. The frame includes a lower disposed in a spaced relationship with a back surface opposite to the light receiving surface, a rising part extending upward from the lower part, and a holding part formed at an end portion of the rising part on a side of the panel to hold one side of the panel. The holding part includes a portion protruding inwardly from the end portion, a portion protruding outwardly from the end portion, a portion extending upwardly from an outside of the outward-protruding portion, and a sandwiching portion extending inwardly from the upward extending portion to sandwich the panel between the sandwiching portion and the outward-protruding portion. The lower part includes a portion protruding inwardly relative to the rising part, and an outward-protruding portion protruding outwardly relative to the rising part.

Abstract: A solar cell module in the present invention includes: a wiring member electrically connecting solar cell elements to each other; and a structure in which a solder bonding portion is formed by bonding a collecting electrode, which is provided on a light receiving surface of the solar cell element, extends in a first direction parallel to the wiring member, and has a width smaller than that of the wiring member in a cross section vertical to the first direction, and the wiring member together by melting solder, a cross-sectional shape of the solder bonding portion vertical to the first direction has a shape that gradually narrows toward the collecting electrode from a lower surface of the wiring member, and a side surface of the solder bonding portion and a side surface of the wiring member are covered with a thermosetting resin.

Abstract: A plurality of thin linear thin wire electrodes are formed entirely over a first surface that is a light receiving surface of a solar cell element, a back surface collecting electrode is formed on a second surface that is a back surface of the solar cell element, and a wiring member which draws power is connected to each of the thin wire electrode and the back surface collecting electrode. The thin wire electrode and the wiring member are bonded with solder and side surfaces of the solder bonding portion in a longitudinal direction along the wiring member are coated with a thermosetting resin, and, in a region excluding the thin wire electrodes, the wiring member and the first surface are bonded with a thermosetting resin. The wiring member and the thin wire electrodes are bonded to have a sufficient mechanical bonding strength and high bonding reliability.

Abstract: In a solar battery cell, a plurality of silver electrodes are formed in a dot shape with a predetermined gap therebetween linearly along a rear surface tab line. Pitches among the silver electrodes are set so as to be large in a central part of a silicon substrate and small at the ends of the silicon substrate. By arranging many silver electrodes at ends of the silicon substrate having a large stress, the rigidity at the ends is improved, and the warpage is decreased, thereby suppressing cell cracking.

Abstract: A solar battery cell that comprises a plurality of grid electrodes and light-receiving-surface lead connection electrodes on a light receiving surface of a semiconductor substrate, and comprises a plurality of back-surface lead connection electrodes that are connected to back-surface lead wires, formed on the second straight lines that are substantially opposite to the first straight lines while sandwiching the semiconductor substrate together with the first straight lines, on a back surface of the semiconductor substrate, wherein an edge portion of each of the light-receiving-surface lead connection electrodes is not overlapped with an edge portion of each of the back-surface lead connection electrodes in a width direction.

Abstract: A solar battery cell includes: a light-receiving-surface bus electrode; a light receiving surface of a semiconductor substrate; and a long lead wire for extracting electricity. The light-receiving-surface bus electrode extends in a predetermined direction on the light receiving surface of the semiconductor substrate and the long lead wire is overlapped on and joined to the light-receiving-surface bus electrode. The light-receiving-surface bus electrode and the lead wire are respectively provided with mutually engaging, without a gap, convex portions and concave portions on surfaces thereof facing each other to regulate misalignment in a width direction between the light-receiving-surface bus electrode and the lead wire.

Abstract: A solar cell module in the present invention includes: a wiring member electrically connecting solar cell elements to each other; and a structure in which a solder bonding portion is formed by bonding a collecting electrode, which is provided on a light receiving surface of the solar cell element, extends in a first direction parallel to the wiring member, and has a width smaller than that of the wiring member in a cross section vertical to the first direction, and the wiring member together by melting solder, a cross-sectional shape of the solder bonding portion vertical to the first direction has a shape that gradually narrows toward the collecting electrode from a lower surface of the wiring member, and a side surface of the solder bonding portion and a side surface of the wiring member are covered with a thermosetting resin.

Abstract: In a solar battery module including a plurality of solar battery elements each including electrodes that are electrically connected by an electrically conductive wiring member, the electrode and the wiring member are welded by solder on the electrode, resin is arranged while covering at least a side surface of a solder-bonded portion between the solder and the electrode, and a wetted height of the resin on a side surface of the wiring member is lower than the top of wiring member, so that welding by the solder can be reinforced and the bonding reliability can be improved.

Abstract: A solar battery cell includes: a light-receiving-surface bus electrode; a light receiving surface of a semiconductor substrate; and a long lead wire for extracting electricity. The light-receiving-surface bus electrode extends in a predetermined direction on the light receiving surface of the semiconductor substrate and the long lead wire is overlapped on and joined to the light-receiving-surface bus electrode. The light-receiving-surface bus electrode and the lead wire are respectively provided with mutually engaging, without a gap, convex portions and concave portions on surfaces thereof facing each other to regulate misalignment in a width direction between the light-receiving-surface bus electrode and the lead wire.

Abstract: A plurality of thin linear thin wire electrodes are formed entirely over a first surface that is a light receiving surface of a solar cell element, a back surface collecting electrode is formed on a second surface that is a back surface of the solar cell element, and a wiring member which draws power is connected to each of the thin wire electrode and the back surface collecting electrode. The thin wire electrode and the wiring member are bonded with solder and side surfaces of the solder bonding portion in a longitudinal direction along the wiring member are coated with a thermosetting resin, and, in a region excluding the thin wire electrodes, the wiring member and the first surface are bonded with a thermosetting resin. The wiring member and the thin wire electrodes are bonded to have a sufficient mechanical bonding strength and high bonding reliability.

Abstract: A solar cell module device includes a solar cell module formed by arranging plural solar battery cells; a reinforcing frame arranged on a back surface of the solar cell module; and a buffer material made of a rigid material and arranged between the solar cell module and the reinforcing frame. The buffer material has a size not causing the back surface of the solar cell module to come in contact with the reinforcing frame when the solar cell module is bent relative to a length of the reinforcing frame in a longitudinal direction. Therefore, the reinforcing frame does not bury into the buffer material, moreover, the buffer material does not abrade by coming in contact with the reinforcing frame.

Abstract: In a solar battery cell, a plurality of silver electrodes are formed in a dot shape with a predetermined gap therebetween linearly along a rear surface tab line. Pitches among the silver electrodes are set so as to be large in a central part of a silicon substrate and small at the ends of the silicon substrate. By arranging many silver electrodes at ends of the silicon substrate having a large stress, the rigidity at the ends is improved, and the warpage is decreased, thereby suppressing cell cracking.

Abstract: A solar battery module device includes a solar cell module formed by arranging a plurality of solar battery cells; a rack-shaped frame having a substantially rectangular shape supporting an outer-edge portion of the solar cell module by surrounding a whole periphery of the outer-edge portion; and a reinforcing frame that is bridged over between two opposite sides of the rack-shaped frame by forming a predetermined gap between the reinforcing frame and a back surface of the solar cell module, and supports the solar cell module by being brought into contact with the back surface of the solar cell module when the solar cell module is bent. The reinforcing frame is engaged with engagement notches formed on the back surface of the rack-shaped frame.

Abstract: A solar battery cell that comprises a plurality of grid electrodes and light-receiving-surface lead connection electrodes on a light receiving surface of a semiconductor substrate, and comprises a plurality of back-surface lead connection electrodes that are connected to back-surface lead wires, formed on the second straight lines that are substantially opposite to the first straight lines while sandwiching the semiconductor substrate together with the first straight lines, on a back surface of the semiconductor substrate, wherein an edge portion of each of the light-receiving-surface lead connection electrodes is not overlapped with an edge portion of each of the back-surface lead connection electrodes in a width direction.

Abstract: A solar battery module device includes a solar cell module formed by arranging a plurality of solar battery cells; a rack-shaped frame having a substantially rectangular shape supporting an outer-edge portion of the solar cell module by surrounding a whole periphery of the outer-edge portion; and a reinforcing frame that is bridged over between two opposite sides of the rack-shaped frame by forming a predetermined gap between the reinforcing frame and a back surface of the solar cell module, and supports the solar cell module by being brought into contact with the back surface of the solar cell module when the solar cell module is bent. The reinforcing frame is engaged with engagement notches formed on the back surface of the rack-shaped frame.

Abstract: A solar cell module device includes a solar cell module formed by arranging plural solar battery cells; a reinforcing frame arranged on a back surface of the solar cell module; and a buffer material made of a rigid material and arranged between the solar cell module and the reinforcing frame. The buffer material has a size not causing the back surface of the solar cell module to come in contact with the reinforcing frame when the solar cell module is bent relative to a length of the reinforcing frame in a longitudinal direction. Therefore, the reinforcing frame does not bury into the buffer material, moreover, the buffer material does not abrade by coming in contact with the reinforcing frame.

Abstract: A solar cell module is structured by laminating a plurality of layers including a cell arrangement layer, on which a plurality of solar battery cells are arranged. To improve the designing property and productivity, in a blank region, which is a region other than where the solar battery cells of the cell arrangement layer are arranged, a thin plate having a color tone same as that of the solar battery cells is arranged. The thin plate is arranged on the cell arrangement layer at a step same as a step in which the solar battery cells are arranged on the cell arrangement layer.