초록 ▼

The invention relates to a holding device for holding glass closures (20) formed by individual glass profile elements, especially U-shaped glass profile elements (21, 21'), or other long glass elements, especially insulating glass elements. In order to prevent water condensation inside the glass clo

The invention relates to a holding device for holding glass closures (20) formed by individual glass profile elements, especially U-shaped glass profile elements (21, 21'), or other long glass elements, especially insulating glass elements. In order to prevent water condensation inside the glass closure (20), the holding device comprises at least one holding rail (2; 32, 36, 37; 34, 64, 65; 34, 64', 76; 79; 80) for holding or mounting and for laterally guiding and supporting the individual long glass elements or glass profile elements (21, 21') or the glass closure (20). Said holding rail (2; 32, 36, 37; 34, 64, 65; 34, 64', 76; 79; 80) has a metal holding segment (3; 38; 54; 69, 77; 87; 88) for holding or supporting a front face area or a partial front face area of the glass closure (20) or individual glass elements or glass profile elements (21, 21') at least one projecting metal flange section (4, 5; 4', 5'; 49, 50; 57, 58; 71, 72; 81, 82) for laterally guiding or supporting the glass closure (20) and/or one, several or all the individual glass elements or glass profile elements (21, 21') thereof, whereby the flange segment (4, 5; 4', 5'; 49, 50; 57, 58; 71, 72; 81, 82) and the holding segment (3; 38; 54; 69, 77; 87; 88) are fixedly connected to one another by means of a heat-insulating and/or thermally separating connecting device (6, 7; 40, 41; 43, 44; 45, 46, 47, 48; 67, 68; 64, 65). The invention also relates to a holding rail that can be used in said holding device.

대표청구항 ▼

The invention relates to a holding device for holding glass closures (20) formed by individual glass profile elements, especially U-shaped glass profile elements (21, 21'), or other long glass elements, especially insulating glass elements. In order to prevent water condensation inside the glass clo

The invention relates to a holding device for holding glass closures (20) formed by individual glass profile elements, especially U-shaped glass profile elements (21, 21'), or other long glass elements, especially insulating glass elements. In order to prevent water condensation inside the glass closure (20), the holding device comprises at least one holding rail (2; 32, 36, 37; 34, 64, 65; 34, 64', 76; 79; 80) for holding or mounting and for laterally guiding and supporting the individual long glass elements or glass profile elements (21, 21') or the glass closure (20). Said holding rail (2; 32, 36, 37; 34, 64, 65; 34, 64', 76; 79; 80) has a metal holding segment (3; 38; 54; 69, 77; 87; 88) for holding or supporting a front face area or a partial front face area of the glass closure (20) or individual glass elements or glass profile elements (21, 21') at least one projecting metal flange section (4, 5; 4', 5'; 49, 50; 57, 58; 71, 72; 81, 82) for laterally guiding or supporting the glass closure (20) and/or one, several or all the individual glass elements or glass profile elements (21, 21') thereof, whereby the flange segment (4, 5; 4', 5'; 49, 50; 57, 58; 71, 72; 81, 82) and the holding segment (3; 38; 54; 69, 77; 87; 88) are fixedly connected to one another by means of a heat-insulating and/or thermally separating connecting device (6, 7; 40, 41; 43, 44; 45, 46, 47, 48; 67, 68; 64, 65). The invention also relates to a holding rail that can be used in said holding device. onally, two input NOR blocks, iterating through all three input NAND blocks, and, optionally, three input NOR block, performing the following steps for each three input NAND, and, optionally, three input NOR: replacing each low threshold voltage instance of said three input NAND and NOR block with a high threshold voltage version of said three input NAND and NOR blocks; reassigning input signals on each said three input NAND and NOR block to logically equivalent inputs by slack, coupling an input with a largest slack to an input on said three input NAND and NOR block with a largest delay characteristic, and an input with a smallest slack to an input on said three input NAND and NOR block with a smallest delay characteristic; recomputing all delays and slacks in paths affected by each replacement of said low threshold three input NAND and NOR blocks, and checking if the replacement results in a negative slack; and restoring each said high threshold voltage replacing three input NAND and NOR block to the original low threshold voltage NAND and NOR block, restoring the signal to input assignments existent prior to the reassignment step, and restoring the delays and slacks to their values prior to the replacement, if slack is found to be negative in the preceding step. election of the path. 7. The decoding method according to claim 6, wherein said control step controls values of state metrics of all the fixed information after a transition of the codes of the fixed information is terminated. 8. The decoding method according to claim 6, wherein said control step controls the value of the state metric of the fixed information positioned at an arbitrary location after a transition of the code of the fixed information is terminated. 9. The decoding method according to claim 6, wherein said control step controls values of state metrics of the fixed information positioned at a plurality of arbitrary locations after a transition of the code of the fixed information is terminated. 10. The decoding method according to claim 6, wherein when states of codes of a plurality of the fixed information obtained after a transition of codes of the plurality of the fixed information is terminated are the same, said control step controls the value of the state metric at one location corresponding to each of the plurality of the fixed information.