CN215720430U - Damper suitable for step load - Google Patents

Abstract

The utility model relates to a damper suitable for step load, which comprises a moving part and a fixed part, wherein the fixed part is fixedly arranged on a structural member, the moving part comprises a top steel plate, a hollow steel pipe, a bent plate and a bottom sliding plate, and the fixed part comprises a steel wall and a bottom steel plate; the damper can enable the damper to have energy dissipation effects in different directions according to the arrangement mode and the size of the bent plates, and is suitable for dynamic loads with different strengths; the movable part and the fixed part are not fixedly connected, and the movable part can be easily replaced when damaged or failed.

Description

Damper suitable for step load

Technical Field

The utility model relates to the field of a structure control system (damping system), in particular to a damper suitable for step load.

Background

As infrastructure age and construction costs increase, engineers have begun to try to extend the useful life of structures to achieve greater sustainability. Structural members of infrastructures such as bridges, buildings and piping systems are often subjected to vibrations caused by dynamic loads such as earthquakes and wind, which need to be effectively controlled to ensure the sustainability and applicability of the infrastructures. Dynamic loading can cause damage and destruction of the structural members, adversely affecting the structure.

The traditional damping method is to provide the system with a large stiffness during the design phase of the structure. However, in view of material and cost issues, it is only allowed to provide a small stiffness at the structural design stage. Currently, there are many measures to effectively control vibrations in structural members. However, most of these measures do not take into account the contraction and expansion of the structure, particularly the bridge, and the temperature load may cause fatigue and reduce the performance and service life of the metal damper. Furthermore, most dampers (passive dampers) are only suitable for earthquakes of a certain strength. When the intensity of the earthquake load is too large and small, the damper may fail or may not work normally because of too large rigidity.

Therefore, it is necessary to employ structural control systems to reduce vibration of the structure due to dynamic loading. Structural control systems that are currently widely used include passive, active, semi-active, and hybrid control systems. Passive control systems are simpler and less expensive than other control systems. However, passive control systems are mostly designed for dynamic excitation of a certain intensity.

Disclosure of Invention

The utility model aims to overcome the defects and provides a damper suitable for step load, which is used for reducing the vibration of a structural member caused by dynamic load. The step-change means that it can be applied to dynamic loads of different strengths, rather than to dynamic loads of a particular strength.

The damper comprises a moving part and a fixed part, wherein the fixed part is fixedly arranged on a pier or other structural members, the moving part comprises a top steel plate, a hollow steel pipe, a bent plate and a bottom sliding plate, and the fixed part comprises a steel wall and a bottom steel plate;

the steel wall is fixedly arranged on the bottom steel plate, the top steel plate cover is arranged at the upper end of the steel wall, the top steel plate can move transversely or longitudinally relative to the fixed part, the upper surface of the top rigid plate is connected with a main beam or other structural members, the hollow steel pipe is positioned in the center of the steel wall and is arranged in the middle of the lower surface of the top steel plate, the bottom sliding plate is arranged at the lower end of the hollow steel pipe, the bottom sliding plate is positioned in the center of the inner bottom of the steel wall, and the plurality of bent plates are arranged on the periphery of the hollow steel pipe;

the bending plates are arc plates, and the arc lengths of the bending plates are the same or different.

Further, the crooked board welding is at hollow steel pipe's surface, four groups crooked boards of hollow steel pipe week side circumference equipartition, and every group crooked board is including at least one crooked board that from top to bottom interval set up.

Further, the crooked board welding is at hollow steel pipe's surface, and side symmetry sets up two sets of crooked boards around the hollow steel pipe, and side symmetry sets up two sets of crooked boards about the hollow steel pipe, and every group crooked board is including at least one crooked board that from top to bottom interval set up, and the crooked board of side is controlled with the crooked board of hollow steel pipe to the crooked board of side crisscross setting around the hollow steel pipe.

Furthermore, the bending plate positioned on the uppermost layer is in contact with the inner wall of the steel wall or has a gap, the bending plate is positioned outside the bending plate positioned on the uppermost layer, and the distance between the outer end of the rest bending plates and the inner wall of the steel wall is not more than the distance between the bending plate positioned on the uppermost layer and the inner wall of the steel wall.

Furthermore, the hollow steel pipe is welded with the top rigid plate, and the bottom sliding plate is welded with the hollow steel pipe.

Furthermore, a plurality of stiffening ribs are uniformly distributed on the outer periphery of the steel wall, the stiffening ribs are welded on the outer surface of the steel wall, and the stiffening ribs and the lower end of the steel wall are welded with the bottom steel plate.

Compared with the prior art, the utility model has the following beneficial effects: the bending plate has a simple structure and reasonable design, can have energy dissipation effects in different directions according to the arrangement mode and the size of the bending plate, is suitable for dynamic loads with different strengths, and is not limited to dynamic loads with certain designed strength; under the condition of not affecting the performance of the absorption structure, the expansion and contraction amount of the absorption structure is caused by the temperature effect, and the movable part and the fixed part are not fixedly connected, so that the movable part can be easily replaced when damaged or failed; meanwhile, the dynamic load limiter plays a role of a limiter, and the bridge can be prevented from falling even if the dynamic load limiter breaks down.

Drawings

The utility model is further described with reference to the following figures.

Figure 1 is a cross-sectional view of the present damper.

Fig. 2 is a schematic structural view of the moving part.

Fig. 3 is a schematic structural view of the fixing portion.

Fig. 4 is an exploded view of the present damper structure.

In the figure: 1-top rigid plate; 2-hollow steel pipe; 3-bending the plate; 4-bottom sliding plate; 5-a steel wall; 6-a stiffening rib; 7-bottom steel plate.

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.

As shown in fig. 1-4, a damper suitable for step load comprises a moving part and a fixed part, wherein the fixed part is fixedly installed on a structural member, the moving part comprises a top steel plate 1, a hollow steel pipe 2, a bent plate 3 and a bottom sliding plate 4, and the fixed part comprises a steel wall 5 and a bottom steel plate 7;

the steel wall is fixedly arranged on the bottom steel plate, the top steel plate cover is arranged at the upper end of the steel wall, the top steel plate can move transversely or longitudinally relative to the fixed part, the upper surface of the top rigid plate is connected with a structural member, the hollow steel pipe is positioned in the center of the steel wall and is arranged in the middle of the lower surface of the top steel plate, the bottom sliding plate is arranged at the lower end of the hollow steel pipe, the bottom sliding plate is positioned in the center of the inner bottom of the steel wall, and the plurality of bent plates are arranged on the periphery of the hollow steel pipe;

the bending plates are arc plates, the arc lengths of the bending plates are the same or different, the bending plates are main energy consumption components, and energy is consumed through bending;

after the stress is applied, the moving part moves relative to the fixed part, and the bending plate and the steel wall are extruded and deformed to consume energy; the movable part and the fixed part are not fixedly connected, and the movable part can be removed, repaired or replaced on site after being damaged or failed.

In this embodiment, the bending plate can have energy dissipation effects in different directions according to the arrangement and size of the bending plate, and is suitable for dynamic loads with different strengths, and is not limited to dynamic loads with a certain design strength.

In the embodiment, the material used by the damper can be metal material such as steel, mild steel and the like, so the energy consumption capability of the damper is influenced by the material characteristics, the height of the hollow steel tube depends on the number and the arc length of the bent plates, and the design of the bent plates depends on the bending radius, the plate thickness, the arc length and the material used.

In this embodiment, the crooked board welding is at hollow steel pipe's surface, four groups crooked boards of hollow steel pipe week side circumference equipartition, and every group crooked board is including at least one crooked board that from top to bottom interval set up.

In this embodiment, the crooked board welding sets up two sets of crooked boards at hollow steel pipe's surface, side symmetry around the hollow steel pipe, and side symmetry sets up two sets of crooked boards about the hollow steel pipe, and every group crooked board is including at least one crooked board that from top to bottom interval set up, and the crooked board of side is controlled with the crooked board of hollow steel pipe to the crooked board of side crisscross setting around the hollow steel pipe.

In this embodiment, the curved plate at the uppermost layer contacts or has a gap with the inner wall of the steel wall, and is located outside the curved plate at the uppermost layer, and the distance between the outer end of the remaining curved plate and the inner wall of the steel wall is not greater than the distance between the curved plate at the uppermost layer and the inner wall of the steel wall.

In this embodiment, the hollow steel tube is welded to the top rigid plate, and the bottom sliding plate is welded to the hollow steel tube.

In this embodiment, a plurality of stiffening ribs 6 are uniformly distributed on the outer periphery of the steel wall, the stiffening ribs are welded on the outer surface of the steel wall, and the stiffening ribs, the lower end of the steel wall and the bottom steel plate are welded.

If this patent discloses or refers to parts or structural elements that are fixedly connected to each other, the fixedly connected may be understood as: a detachable fixed connection (for example using bolts or screws) is also understood as: non-detachable fixed connections (e.g. riveting, welding), but of course, fixed connections to each other may also be replaced by one-piece structures (e.g. manufactured integrally using a casting process) (unless it is obviously impossible to use an integral forming process).

In the description of this patent, it is to be understood that the terms "longitudinal," "lateral," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the patent, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and are not to be considered limiting of the patent.

The above-mentioned preferred embodiments, further illustrating the objects, technical solutions and advantages of the present invention, should be understood that the above-mentioned are only preferred embodiments of the present invention and should not be construed as limiting the present invention, and any modifications, equivalents, improvements and the like made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (5)

1. A damper suitable for step load is characterized in that: the movable part comprises a top steel plate, a hollow steel pipe, a bent plate and a bottom sliding plate, and the fixed part comprises a steel wall and a bottom steel plate;

the steel wall is fixedly arranged on the bottom steel plate, the top steel plate cover is arranged at the upper end of the steel wall, the top steel plate can move transversely or longitudinally relative to the fixed part, the upper surface of the top rigid plate is connected with a main beam or other structural members, the hollow steel pipe is positioned in the center of the steel wall and is arranged in the middle of the lower surface of the top steel plate, the bottom sliding plate is arranged at the lower end of the hollow steel pipe, the bottom sliding plate is positioned in the center of the inner bottom of the steel wall, and the plurality of bent plates are arranged on the periphery of the hollow steel pipe;

the bending plate is an arc plate.

2. The damper adapted for step loads according to claim 1, wherein: the crooked board welding is at hollow steel pipe's surface, four group crooked boards of hollow steel pipe week side circumference equipartition, and every group crooked board is including at least one crooked board that from top to bottom interval set up.

3. The damper adapted for step loads according to claim 1, wherein: the crooked board welding sets up two sets of crooked boards at hollow steel pipe's surface, side symmetry around the hollow steel pipe, and side symmetry sets up two sets of crooked boards about the hollow steel pipe, and every group crooked board is including at least one crooked board that from top to bottom interval set up, and the crooked board of side is controlled with the crooked board of hollow steel pipe to the crooked board of side crisscross setting around the hollow steel pipe.

4. The damper adapted for step loads according to claim 1, wherein: the hollow steel pipe is welded with the top rigid plate, and the bottom sliding plate is welded with the hollow steel pipe.

5. The damper adapted for step loads according to claim 1, wherein: and a plurality of stiffening ribs are uniformly distributed on the outer periphery of the steel wall, the stiffening ribs are welded on the outer surface of the steel wall, and the stiffening ribs, the lower end of the steel wall and the bottom steel plate are welded.

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