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Tensile friction pendulum support structure for glass daylighting roof structure and construction method of tensile friction pendulum support structure
The invention discloses a tensile friction pendulum support structure for a glass daylighting roof structure and a construction method of the tensile friction pendulum support structure, and the tensile friction pendulum support structure comprises a support body which comprises an upper support plate and a lower support plate which are oppositely arranged, and a sliding plate is slidably arranged between the upper support plate and the lower support plate; a bearing platform plate is embedded in the upper portion of the foundation structure, the lower support plate is installed on the bearing platform plate, a plurality of first penetrating holes are formed in the bearing platform plate, lower anchor rods are arranged in the first penetrating holes in a penetrating mode, and the upper ends of the lower anchor rods extend to the positions above the first penetrating holes; the upper support plate is supported on the daylighting roof structure, a plurality of second penetrating holes are formed in the upper support plate, upper anchor rods are arranged in the second penetrating holes in a penetrating mode, and the lower ends of the upper anchor rods extend to the positions below the second penetrating holes; the two ends of the tensile cable are detachably installed between the upper anchor rod and the lower anchor rod. The problem that a friction pendulum support adopted on an existing glass light roof structure cannot resist vertical pulling resistance is solved.
本发明公开了一种用于玻璃采光顶结构的抗拉摩擦摆支座结构及其施工方法,包括:支座本体,包括相对设置的上支座板和下支座板,上支座板与下支座板之间滑设有滑动板;基础结构,基础结构的上部埋设有承台板,下支座板安装于承台板,承台板开设有多个第一穿孔,第一穿孔穿设有下锚杆,下锚杆的上端伸至第一穿孔的上方;采光顶结构,上支座板支撑于采光顶结构,上支座板开设有多个第二穿孔,第二穿孔中穿设有上锚杆,上锚杆的下端伸至第二穿孔的下方;抗拉索,抗拉索的两端可拆卸地安装于上锚杆和下锚杆之间。本发明解决了现有的玻璃光顶结构上采用的摩擦摆支座不能抵抗竖向抗拔力的问题。
Tensile friction pendulum support structure for glass daylighting roof structure and construction method of tensile friction pendulum support structure
The invention discloses a tensile friction pendulum support structure for a glass daylighting roof structure and a construction method of the tensile friction pendulum support structure, and the tensile friction pendulum support structure comprises a support body which comprises an upper support plate and a lower support plate which are oppositely arranged, and a sliding plate is slidably arranged between the upper support plate and the lower support plate; a bearing platform plate is embedded in the upper portion of the foundation structure, the lower support plate is installed on the bearing platform plate, a plurality of first penetrating holes are formed in the bearing platform plate, lower anchor rods are arranged in the first penetrating holes in a penetrating mode, and the upper ends of the lower anchor rods extend to the positions above the first penetrating holes; the upper support plate is supported on the daylighting roof structure, a plurality of second penetrating holes are formed in the upper support plate, upper anchor rods are arranged in the second penetrating holes in a penetrating mode, and the lower ends of the upper anchor rods extend to the positions below the second penetrating holes; the two ends of the tensile cable are detachably installed between the upper anchor rod and the lower anchor rod. The problem that a friction pendulum support adopted on an existing glass light roof structure cannot resist vertical pulling resistance is solved.
本发明公开了一种用于玻璃采光顶结构的抗拉摩擦摆支座结构及其施工方法,包括:支座本体,包括相对设置的上支座板和下支座板,上支座板与下支座板之间滑设有滑动板;基础结构,基础结构的上部埋设有承台板,下支座板安装于承台板,承台板开设有多个第一穿孔,第一穿孔穿设有下锚杆,下锚杆的上端伸至第一穿孔的上方;采光顶结构,上支座板支撑于采光顶结构,上支座板开设有多个第二穿孔,第二穿孔中穿设有上锚杆,上锚杆的下端伸至第二穿孔的下方;抗拉索,抗拉索的两端可拆卸地安装于上锚杆和下锚杆之间。本发明解决了现有的玻璃光顶结构上采用的摩擦摆支座不能抵抗竖向抗拔力的问题。
Tensile friction pendulum support structure for glass daylighting roof structure and construction method of tensile friction pendulum support structure
用于玻璃采光顶结构的抗拉摩擦摆支座结构及其施工方法
LIU JIAN (Autor:in) / JIN GUODONG (Autor:in) / ZHANG HANJIE (Autor:in) / YANG QIN (Autor:in) / GE YIN (Autor:in) / ZHANG WENHAO (Autor:in) / LIU HONGGENG (Autor:in) / DING JINHUI (Autor:in) / GAO XIAODONG (Autor:in)
23.05.2023
Patent
Elektronische Ressource
Chinesisch
Composite tensile friction pendulum shock insulation support
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