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CN-224225802-U - Container and stacked container structure with shock-absorbing and isolating connection nodes

CN224225802UCN 224225802 UCN224225802 UCN 224225802UCN-224225802-U

Abstract

The utility model discloses a container and a stacked container structure with shock-absorbing and shock-insulating connecting nodes, which relates to the technical field of containers, wherein the main structure of the container is a cuboid frame and comprises corner pieces positioned at four corners of the container, corner posts positioned on a vertical plane, top beams and bottom beams positioned on a horizontal plane and connecting boxes, the corner fitting is welded with the connecting box respectively on two adjacent side surfaces of the corner fitting, the corner fitting is welded with the top beam/bottom beam through the connecting box, and the end part of the corner post is welded with the bottom surface/top surface of the corner fitting and the side surface of the connecting box. The stacked container structure comprises a plurality of containers and shock-absorbing and isolating connection nodes, the containers are divided into at least two groups of boxes, the at least two groups of boxes are stacked from bottom to top in groups, and the shock-absorbing and isolating connection nodes are arranged between the two groups of boxes which are adjacent from top to bottom. The container is convenient to connect with the shock absorption and isolation connecting nodes to form a stacked container structure, so that stable connection of a plurality of containers is realized.

Inventors

  • LIU SHUZHI
  • LI JUNSHAN
  • SUN ZHEN
  • LI XIANGHUA
  • GUO SENSEN

Assignees

  • 浪潮通信信息系统有限公司

Dates

Publication Date
20260512
Application Date
20250523

Claims (7)

  1. 1. The utility model provides a container, its characterized in that, its major structure is cuboid frame, including the corner fittings that is located four bights of container, be in the corner post of vertical plane, be in roof beam and floorbar in the horizontal plane, and connect the box, wherein, two adjacent side welding connection boxes respectively of corner fittings, and the corner fittings passes through roof beam/floorbar welded connection in connection box and the horizontal plane, the bottom surface/top surface of corner post tip welded connection corner fittings in the vertical plane and the side of connection box.
  2. 2. A container according to claim 1, wherein the connecting box is an E-shaped structure formed by welding four steel plates, the E-shaped structure of the connecting box is located in a horizontal plane, and the E-shaped opening faces the corner pieces and the corner posts; The E-shaped left side surface of the connecting box is in butt contact with the top beam/bottom beam and is welded and connected; The E-shaped opening end face of the connecting box is welded with the connecting corner piece, the corner post and the E-shaped top face of the other connecting box on the adjacent side face of the corner piece to form a working space for bolt installation operation.
  3. 3. A container according to claim 2, wherein the header/sill, E-shaped structural connection boxes, corner pieces and corner posts together form a stable corner of the container by welding, ultimately forming an integrally welded cuboid frame.
  4. 4. The stacked container structure with the shock-absorbing and shock-insulating connecting nodes is characterized by comprising a plurality of containers and the shock-absorbing and shock-insulating connecting nodes, wherein the containers are divided into at least two groups of boxes, the at least two groups of boxes are stacked in groups from bottom to top, and the shock-absorbing and shock-insulating connecting nodes are arranged between the two groups of boxes which are adjacent from top to bottom; The main structure of the container is a cuboid frame and comprises corner pieces positioned at four corners of the container, corner posts positioned in a vertical plane, top beams and bottom beams positioned in a horizontal plane and connecting boxes, wherein the connecting boxes are respectively arranged on two adjacent side surfaces of the corner pieces, the bottom surfaces/top surfaces of the corner pieces are welded at the end parts of the corner posts in the vertical plane, the connecting boxes are E-shaped structures formed by welding four steel plates, the E-shaped structures of the connecting boxes are positioned in the horizontal plane, E-shaped openings face the corner pieces and the corner posts, the E-shaped left side surfaces of the connecting boxes are in butt contact with the top beams/bottom beams and are welded with the E-shaped opening end surfaces of the connecting boxes, the corner posts and the E-shaped top surfaces of the other connecting boxes on the adjacent side surfaces of the corner pieces, so that a working space for bolt installation operation is formed; The shock-absorbing and isolating connecting node comprises a rubber support, connecting plates and connecting box end plates, wherein the connecting plates are symmetrically arranged on the upper side and the lower side of the rubber support, the connecting plates are located between the rubber support and the connecting box end plates, the connecting box end plates are welded on the E-shaped surface of the connecting box, and bolts sequentially penetrate through the connecting box end plates of the container below the welded connection, the connecting plates below the rubber support, the connecting plates above the rubber support and the connecting box end plates of the container above the welded connection and then are fastened with locking nuts.
  5. 5. The stacked container structure with shock absorbing and insulating connection nodes of claim 4, wherein two connection box end plates are arranged above or below the connection plate, and the two connection box end plates correspond to E-shaped surfaces of the connection boxes welded on two adjacent side surfaces of the corner piece; at least two screws pass through the end plate of the same connecting box and then pass through the connecting plate below the rubber support, the connecting plate above the rubber support and the connecting box end plate of the container above correspondingly welded and connected, and then are fastened and connected with the locking nut.
  6. 6. The stacked container structure with shock-absorbing and insulating connection nodes according to claim 4, wherein the plurality of containers are divided into at least two groups of containers, the at least two groups of containers are stacked from bottom to top in groups, shock-absorbing and insulating connection nodes are arranged between the two groups of containers adjacent from top to bottom, when each group of containers comprises the at least two containers, two rubber supports are integrally connected in the two shock-absorbing and insulating connection nodes adjacent from left to right, two corresponding connection plates above the rubber supports are integrally connected, and two corresponding connection plates below the rubber supports are integrally connected.
  7. 7. The stacked container structure with shock absorbing and isolating connection nodes according to claim 6, wherein two single-sided cones are symmetrically welded on the lower surface of the connecting plate integrally connected below the rubber support, and two single-sided cones are symmetrically welded on the upper surface of the connecting plate integrally connected above the rubber support; Two single-sided cones welded on the same connecting plate are correspondingly embedded on the bottom surfaces/top surfaces of corner fittings in two containers adjacent left and right.

Description

Container and stacked container structure with shock-absorbing and isolating connection nodes Technical Field The utility model relates to the technical field of containers, in particular to a container and a stacked container structure with shock-absorbing and shock-insulating connection nodes. Background With the rapid development of modular construction technology and the rapid growth of computing demands, stacked container structures are increasingly being used in the data center field. At present, a rigid connection mode (such as welding, bolt fixing and the like) is adopted for the connection nodes of the stacked container, so that the structural integrity can be guaranteed under the general condition, however, in a high-intensity earthquake area, the earthquake resistance of the stacked container structure faces a serious challenge, the connection nodes are easy to cause stress concentration under the action of an earthquake, and an effective energy dissipation mechanism is lacked, so that the local damage and even the whole overturning of the structure can be possibly caused. Disclosure of Invention The utility model provides a container and a stacked container structure with shock-absorbing and isolating connection nodes, which aim at the needs and the defects of the prior art development. In a first aspect, the present utility model provides a container, which solves the above technical problems by adopting the following technical scheme: The utility model provides a container, its major structure is cuboid frame, including the corner fittings that is located four bights of container, the corner post that is in vertical plane, the back timber and the roof beam that are in the horizontal plane and connection box, wherein, two adjacent sides of corner fittings welded connection box respectively, and the corner fittings passes through the back timber/roof beam welded connection in connection box and the horizontal plane, the bottom surface/top surface of corner post tip welded connection corner fittings in the vertical plane and the side of connection box. Optionally, the connecting box is an E-shaped structure formed by welding four steel plates, the E-shaped structure of the connecting box is positioned in a horizontal plane, and the E-shaped opening faces the corner fitting and the corner post; the E-shaped left side surface of the connecting box is in butt contact with the top beam/bottom beam and is welded and connected; the E-shaped opening end face of the connecting box is welded with the connecting corner piece, the corner post and the E-shaped top face of the other connecting box on the adjacent side face of the corner piece to form a working space for bolt installation operation. Further optionally, the roof beam/sill, the E-shaped structural connection box, corner fittings and corner posts involved together form a stable corner of the container by welding, ultimately forming an integrally welded cuboid frame. In a second aspect, the present utility model provides a stacked container structure with shock-absorbing and isolating connection nodes, which solves the above technical problems by adopting the following technical scheme: A stacked container structure with shock-absorbing and shock-insulating connection nodes comprises a plurality of containers and the shock-absorbing and shock-insulating connection nodes, wherein the containers are divided into at least two groups of boxes, the at least two groups of boxes are stacked in groups from bottom to top, and the shock-absorbing and shock-insulating connection nodes are arranged between the two groups of boxes which are adjacent from top to bottom; The main structure of the container is a cuboid frame and comprises corner pieces positioned at four corners of the container, corner posts positioned in a vertical plane, top beams and bottom beams positioned in a horizontal plane and connecting boxes, wherein the connecting boxes are respectively arranged on two adjacent side surfaces of the corner pieces, the bottom surfaces/top surfaces of the corner pieces are welded and connected at the end parts of the corner posts in the vertical plane; The shock-absorbing and isolating connecting node comprises a rubber support, connecting plates and connecting box end plates, wherein the connecting plates are symmetrically arranged on the upper side and the lower side of the rubber support, the connecting plates are located between the rubber support and the connecting box end plates, the connecting box end plates are welded on the E-shaped surface of the connecting box, and bolts sequentially penetrate through the connecting box end plates of the container below the welded connection, the connecting plates below the rubber support, the connecting plates above the rubber support and the connecting box end plates of the container above the welded connection and then are fastened and connected with locking nuts. Optionally, two connecting box end plates