CN216276189U - A shock attenuation combination formula connection structure for architectural design engineering - Google Patents

Abstract

The utility model relates to the technical field of building design engineering, in particular to a damping combined connecting structure for building design engineering, which comprises a damping support arranged at the lower end of a steel pillar, the damping device comprises a damping support, a base arranged at the lower end of the damping support, a fixing mechanism is connected to the upper end of the base in a penetrating mode, a connecting block is movably connected to the inner wall of the damping support, a mounting groove is formed in the upper end of the connecting block, a buffer block is fixedly connected to the lower end of the connecting block, a bearing block is arranged at the lower end of the buffer block, a buffer groove is formed in the upper end of the bearing block, the buffer block is movably connected to the inner wall of the buffer groove, a reset spring is fixedly connected to the inner cavity bottom plate of the buffer groove, one end of the reset spring is fixedly connected with the buffer block, and a buffer assembly is movably arranged at the lower end of the bearing block.

Description

A shock attenuation combination formula connection structure for architectural design engineering

Technical Field

The utility model relates to the technical field of architectural design engineering, in particular to a damping combined connecting structure for architectural design engineering.

Background

The building engineering refers to an engineering entity formed by the construction of various building constructions and their auxiliary facilities and the installation of lines, pipelines and equipment matched with them. The house building is characterized by comprising a top cover, a beam column, a wall, a foundation and a project which can form an internal space and meet the requirements of people on production, living, study and public activities.

However, the conventional steel structure building structure is slightly insufficient in damping effect, and the steel column is likely to be inclined in a severe environment, which results in high risk.

In order to solve the problems, the utility model provides a damping combined connecting structure for building design engineering.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a damping combined connecting structure for building design engineering, wherein the upper end of a connecting block is provided with a mounting groove, the lower end of the connecting block is fixedly connected with a buffer block, the lower end of the buffer block is provided with a bearing block, the upper end of the bearing block is provided with a buffer groove, the buffer block is movably connected with the inner wall of the buffer groove, an inner cavity bottom plate of the buffer groove is fixedly connected with a return spring, one end of the return spring is fixedly connected with the buffer block, the lower end of the bearing block is movably provided with a buffer component, the buffer block is in a circular truncated cone shape, the buffer groove is in a trapezoid shape, the lower ends of a first upper connecting rod and a second upper connecting rod are respectively hinged with a first connecting block and a second connecting block, the lower ends of the first connecting block and the second connecting block are respectively hinged with a first lower connecting rod and a second lower connecting rod, the buffer spring is fixedly connected between the first connecting block and the second connecting block, and the first connecting block and the second connecting block are symmetrically distributed on the buffer block about the center of the buffer spring, thereby solving the problems in the background art.

In order to achieve the purpose, the utility model provides the following technical scheme: a shock attenuation combination formula connection structure for architectural design engineering, including installing the shock absorber at the steel pillar lower extreme to and install the base at the shock absorber lower extreme, the upper end through connection of base has a fixed establishment, the inner wall swing joint of shock absorber has the connecting block, and the mounting groove has been seted up to the upper end of connecting block, and the lower extreme fixedly connected with buffer block of connecting block, the lower extreme of buffer block are provided with and hold the piece, hold the upper end of piece and have seted up the dashpot, buffer block swing joint is at the inner wall of dashpot, fixedly connected with reset spring on the inner chamber bottom plate of dashpot, reset spring's one end and buffer block fixed connection, the lower extreme activity of holding the piece is provided with the buffering subassembly.

Preferably, the shape of the buffer block is a truncated cone shape, and the shape of the buffer groove is a trapezoid shape.

Preferably, the buffer block is a member made of rubber, and the maximum diameter of the buffer block is larger than the minimum diameter of the inner cavity of the buffer groove.

Preferably, the buffering component comprises a first upper connecting rod and a second upper connecting rod which are hinged to the lower end of the bearing block, the lower ends of the first upper connecting rod and the second upper connecting rod are respectively hinged to a first connecting block and a second connecting block, the lower ends of the first connecting block and the second connecting block are respectively hinged to a first lower connecting rod and a second lower connecting rod, and a buffering spring is fixedly connected between the first connecting block and the second connecting block.

Preferably, the first link and the second link are symmetrically distributed about the center of the buffer spring.

Preferably, the fixing mechanism comprises an outer rod and a threaded inner rod arranged in the inner cavity of the outer rod, the outer wall of the threaded inner rod is provided with a movable block, the lower end of the movable block is fixedly connected with a push rod, the lower end of the push rod is fixedly connected with a reinforcing rod, and the lower end of the reinforcing rod is fixedly connected with a fixing nail.

Preferably, the installation piece is installed to the inner chamber of anchor strut, and the equal fixedly connected with connecting rod in both sides of installation piece, the outer wall of connecting rod has cup jointed the promotion spring, promotes the one end and the installation piece fixed connection of spring, and its other end fixedly connected with anchor strut, connecting rod swing joint is at the inner chamber of anchor strut.

Preferably, the movable block is in threaded connection with the threaded inner rod, and the movable block is movably connected with the inner wall of the outer rod.

Compared with the prior art, the utility model has the following beneficial effects:

1. the utility model provides a damping combined connecting structure for building design engineering, wherein the upper end of a connecting block is provided with a mounting groove, the lower end of the connecting block is fixedly connected with a buffer block, the lower end of the buffer block is provided with a bearing block, the upper end of the bearing block is provided with a buffer groove, the buffer block is movably connected with the inner wall of the buffer groove, a return spring is fixedly connected on the bottom plate of the inner cavity of the buffer groove, one end of the return spring is fixedly connected with the buffer block, the lower end of the bearing block is movably provided with a buffer component, the buffer block is in a circular truncated cone shape, the buffer groove is in a trapezoid shape, when a steel strut is strongly impacted, impact force is firstly transmitted to the buffer block through the connecting block to drive the buffer block to move downwards in the inner cavity of the buffer groove, and because the buffer block is a component made of rubber material, the maximum diameter of the buffer block is larger than the minimum diameter of the inner cavity of the buffer groove, the downward moving speed of the buffer block can be gradually reduced, thereby cushion impact force, the effect of impact resistance has been improved to rethread reset spring's effort, and the shock attenuation effect is showing, and the phenomenon of slope is difficult for appearing under the adverse circumstances to the steel pillar, and the security is high.

2. The utility model provides a damping combined connecting structure for building design engineering, wherein the lower ends of a first upper connecting rod and a second upper connecting rod are respectively hinged with a first connecting block and a second connecting block, the lower ends of the first connecting block and the second connecting block are respectively hinged with a first lower connecting rod and a second lower connecting rod, a buffer spring is fixedly connected between the first connecting block and the second connecting block, the first connecting block and the second connecting block are symmetrically distributed about the center of the buffer spring, when the buffer block moves downwards in an inner cavity of a buffer groove, a bearing block can be driven to slowly move downwards, at the moment, the first connecting block and the second connecting block are driven to laterally pull the buffer spring through the matching use of the first upper connecting rod, the second upper connecting rod, the first lower connecting rod and the second lower connecting rod, and the self elasticity of the buffer spring can resist the pulling force, so that the impact force is further weakened, and the damping effect is further improved.

3. The utility model provides a damping combined connecting structure for building design engineering, wherein the outer wall of a threaded inner rod is provided with a movable block, the lower end of the movable block is fixedly connected with a push rod, the lower end of the push rod is fixedly connected with a reinforcing rod, the lower end of the reinforcing rod is fixedly connected with a fixing nail, an inner cavity of the reinforcing rod is provided with an installation block, two sides of the installation block are both fixedly connected with connecting rods, the outer wall of each connecting rod is sleeved with a pushing spring, one end of each pushing spring is fixedly connected with the installation block, the other end of each pushing spring is fixedly connected with a reinforcing block, each connecting rod is movably connected with the inner cavity of the reinforcing block, each movable block is in threaded connection with the threaded inner rod, each movable block is movably connected with the inner wall of an outer rod, when a damping support is fixed, the outer rod penetrates through a base, then the threaded inner rod is rotated to drive the movable block to move downwards along the inner wall of the outer rod, the reinforcing rod and the fixing nail are driven to be inserted into the ground through the push rod, when the reinforcing rod is on the ground, the reinforcing block can be in the inner cavity of the reinforcing rod under extrusion, the thrust of the pushing spring can drive the reinforcing block to tightly fit with the soil, the friction force is improved, and the stability of the damping support is improved.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the internal structure of the shock mount of the present invention;

FIG. 3 is a schematic view of a buffer assembly according to the present invention;

FIG. 4 is a schematic structural view of a fixing mechanism of the present invention;

fig. 5 is a schematic view of the internal structure of the reinforcing bar of the present invention.

In the figure: 1. a shock-absorbing support; 2. a base; 3. a fixing mechanism; 4. connecting blocks; 5. mounting grooves; 6. a buffer block; 7. a bearing block; 8. a buffer tank; 9. a return spring; 10. a buffer assembly; 101. a first upper connecting rod; 102. a second upper connecting rod; 103. a first connecting block; 104. a second connecting block; 105. a first lower connecting rod; 106. a second lower connecting rod; 107. a buffer spring; 31. an outer rod; 32. a threaded inner rod; 33. a movable block; 34. a push rod; 35. a reinforcing rod; 36. fixing nails; 37. mounting blocks; 38. a connecting rod; 39. a push spring; 310. and a reinforcing block.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In order to improve the damping effect of the steel structure building structure, as shown in fig. 1 to 3, the following preferable technical solutions are provided:

a shock attenuation combination formula connection structure for building design engineering, including installing at the shock absorber support 1 of steel pillar lower extreme, and install at the base 2 of shock absorber support 1 lower extreme, the upper end through connection of base 2 has fixed establishment 3, the inner wall swing joint of shock absorber support 1 has connecting block 4, the upper end of connecting block 4 has seted up mounting groove 5, the lower extreme of connecting block 4 is fixedly connected with buffer block 6, the lower extreme of buffer block 6 is provided with and accepts piece 7, the upper end of accepting piece 7 has seted up dashpot 8, buffer block 6 swing joint is at the inner wall of dashpot 8, fixedly connected with reset spring 9 on the inner chamber bottom plate of dashpot 8, one end of reset spring 9 is fixedly connected with buffer block 6, the lower extreme of accepting piece 7 is movably provided with buffer unit 10, buffer block 6 shape is the round platform shape, the shape of dashpot 8 is the trapezoidal, buffer block 6 is the component that the rubber material made, the maximum diameter of the buffer block 6 is larger than the minimum diameter of the inner cavity of the buffer groove 8.

The buffer assembly 10 comprises a first upper connecting rod 101 and a second upper connecting rod 102 which are hinged at the lower end of the bearing block 7, the lower ends of the first upper connecting rod 101 and the second upper connecting rod 102 are respectively hinged with a first connecting block 103 and a second connecting block 104, the lower ends of the first connecting block 103 and the second connecting block 104 are respectively hinged with a first lower connecting rod 105 and a second lower connecting rod 106, a buffer spring 107 is fixedly connected between the first connecting block 103 and the second connecting block 104, and the first connecting block 103 and the second connecting block 104 are symmetrically distributed about the center of the buffer spring 107.

Specifically, when the steel pillar received strong impact, at first can transmit impact force to buffer block 6 through connecting block 4, drive buffer block 6 at the inner chamber downstream of dashpot 8, because of the component that buffer block 6 was made for the rubber material, buffer block 6's maximum diameter is greater than the minimum diameter of buffer pot 8 inner chamber, so move down speed and can progressively slow down at buffer block 6, thereby cushion impact force, rethread reset spring 9's effort, impact resistance's effect has been improved, the shock attenuation effect is showing.

When the buffer block 6 moves downwards in the inner cavity of the buffer groove 8, the receiving block 7 is driven to move downwards slowly, at the moment, the first connecting block 103 and the second connecting block 104 are driven to laterally pull the buffer spring 107 through the matching of the first upper connecting rod 101, the second upper connecting rod 102, the first lower connecting rod 105 and the second lower connecting rod 106, the self elasticity of the buffer spring 107 is utilized, the tensile force can be resisted, the impact force is further weakened, and the damping effect is further improved.

In order to improve the stability of the shock mount, as shown in fig. 4-5, the following preferred technical solutions are provided:

fixed establishment 3 includes outer pole 31, and set up the interior pole 32 of screw thread in the outer pole 31 inner chamber, the outer wall of interior pole 32 of screw thread is provided with movable block 33, the lower extreme fixedly connected with push rod 34 of movable block 33, the lower extreme fixedly connected with anchor strut 35 of push rod 34, the lower extreme fixedly connected with staple 36 of anchor strut 35, installation piece 37 is installed to the inner chamber of anchor strut 35, the equal fixedly connected with connecting rod 38 in both sides of installation piece 37, the outer wall of connecting rod 38 has cup jointed push spring 39, push spring 39's one end and installation piece 37 fixed connection, and its other end fixedly connected with anchor strut 310, connecting rod 38 swing joint is at the inner chamber of anchor strut 310, movable block 33 and the interior pole 32 threaded connection of screw thread, and the inner wall swing joint of movable block 33 and outer pole 31.

Specifically, when fixing shock mount 1, at first utilize outer pole 31 screw thread to run through base 2, then rotate threaded inner pole 32, drive movable block 33 and move down along the inner wall of outer pole 31, drive anchor strut 35 and staple 36 through push rod 34 and insert ground, when anchor strut 35 is in the ground, anchor strut 310 can be in the inner chamber of anchor strut 35 under the extrusion, can drive anchor strut 310 through the thrust of propelling spring 39 and tightly laminate soil, improve frictional force, improved shock mount 1's stability.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. A shock attenuation combination formula connection structure for architectural design engineering, including installing at shock absorber (1) of steel pillar lower extreme to and install base (2) at shock absorber (1) lower extreme, the upper end through connection of base (2) has fixed establishment (3), its characterized in that: the inner wall swing joint of shock absorber support (1) has connecting block (4), mounting groove (5) have been seted up to the upper end of connecting block (4), lower extreme fixedly connected with buffer block (6) of connecting block (4), the lower extreme of buffer block (6) is provided with and holds receiving block (7), buffer slot (8) have been seted up to the upper end of holding receiving block (7), buffer block (6) swing joint is at the inner wall of buffer slot (8), fixedly connected with reset spring (9) on the inner chamber bottom plate of buffer slot (8), the one end and buffer block (6) fixed connection of reset spring (9), the lower extreme activity of holding receiving block (7) is provided with buffer unit (10).

2. The shock-absorbing modular connection structure for construction design engineering according to claim 1, wherein: the buffer block (6) is in a round table shape, and the buffer groove (8) is in a trapezoid shape.

3. The shock-absorbing modular connection structure for construction design engineering according to claim 2, wherein: the buffer block (6) is a component made of rubber materials, and the maximum diameter of the buffer block (6) is larger than the minimum diameter of the inner cavity of the buffer groove (8).

4. The shock-absorbing modular connection structure for construction design engineering according to claim 1, wherein: the buffer assembly (10) comprises a first upper connecting rod (101) and a second upper connecting rod (102) which are hinged to the lower end of a bearing block (7), the lower ends of the first upper connecting rod (101) and the second upper connecting rod (102) are respectively hinged to a first connecting block (103) and a second connecting block (104), the lower ends of the first connecting block (103) and the second connecting block (104) are respectively hinged to a first lower connecting rod (105) and a second lower connecting rod (106), and a buffer spring (107) is fixedly connected between the first connecting block (103) and the second connecting block (104).

5. The shock-absorbing modular connection structure for construction design engineering according to claim 4, wherein: the first connecting block (103) and the second connecting block (104) are symmetrically distributed around the center of the buffer spring (107).

6. The shock-absorbing modular connection structure for construction design engineering according to claim 1, wherein: the fixing mechanism (3) comprises an outer rod (31) and a threaded inner rod (32) arranged in an inner cavity of the outer rod (31), wherein a movable block (33) is arranged on the outer wall of the threaded inner rod (32), a push rod (34) is fixedly connected to the lower end of the movable block (33), a reinforcing rod (35) is fixedly connected to the lower end of the push rod (34), and a fixing nail (36) is fixedly connected to the lower end of the reinforcing rod (35).

7. The shock-absorbing modular connection structure for construction design engineering according to claim 6, wherein: installation piece (37) are installed to the inner chamber of anchor strut (35), the equal fixedly connected with connecting rod (38) in both sides of installation piece (37), and the outer wall of connecting rod (38) has cup jointed promotion spring (39), and the one end and the installation piece (37) fixed connection of promotion spring (39), and its other end fixedly connected with anchor strut (310), connecting rod (38) swing joint is in the inner chamber of anchor strut (310).

8. The shock-absorbing modular connection structure for construction design engineering according to claim 6, wherein: the movable block (33) is in threaded connection with the threaded inner rod (32), and the movable block (33) is movably connected with the inner wall of the outer rod (31).

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