Anti-seismic support of electromechanical equipment in building
Technical Field
The utility model belongs to the technical field of the antidetonation support, more specifically say, in particular to building inside electromechanical device's antidetonation support.
Background
The electromechanical products refer to the sum of mechanical and electrical equipment, along with the progress of scientific technology, the varieties of the electromechanical products in the traditional sense are greatly developed, the electromechanical products in the general concepts in modern technology and management generally refer to mechanical products, electrical products, electronic products, electromechanical integrated products, parts, accessories and the like of the products, and the electromechanical equipment in a building is usually required to be fixedly supported by an anti-seismic support and be subjected to ballasting work.
One is that the existing anti-seismic support cannot produce effective anti-seismic effect, when receiving vibration, the vibration cannot be quickly attenuated, and the anti-seismic effect is poor; moreover, the connection mode of the shock absorption connecting seat of the traditional shock absorption support is single, the structure is complex, and the support fixing piece is inconvenient to install.
Therefore, in view of the above, research and improvement are made for the existing structure and defects, and an anti-seismic support for electromechanical equipment inside a building is provided, so as to achieve the purpose of higher practical value.
SUMMERY OF THE UTILITY MODEL
In order to solve the technical problem, the utility model provides an anti-seismic support for electromechanical equipment in a building, which aims to solve the problems that the existing anti-seismic support can not generate effective anti-seismic effect, can not quickly attenuate the vibration when receiving the vibration, and has poor anti-seismic effect; moreover, the connection mode of the shock absorption connecting seat of the traditional shock absorption support is single, the structure is complex, and the supporting and fixing piece is inconvenient to mount.
The utility model relates to a purpose and efficiency of inside electromechanical device's of building antidetonation support are reached by following specific technological means:
an anti-seismic support for electromechanical equipment inside a building comprises electromechanical equipment; four groups of first anti-seismic structures are mounted at the bottom of the electromechanical equipment, and a second anti-seismic structure is further mounted at the bottom of the electromechanical equipment; the second anti-seismic structure comprises a connecting plate C, a left connecting block, a connecting plate D, an anti-seismic spring and a limiting rod, the tail end of the connecting plate C is rotatably connected with the left side of the connecting seat, and the head end of the connecting plate C is rotatably connected with the left connecting block; the tail end of the connecting plate D is rotatably connected with the left connecting block; the anti-seismic spring is welded between the right connecting block and the left connecting block, and the limiting rod is connected in the right connecting block and the left connecting block in a sliding mode.
Furthermore, the electromechanical device comprises a mounting plate, a shock pad, bolts, a support frame, a sliding chute and mounting holes, wherein the shock pad is arranged on the mounting plate, the electromechanical device is placed on the shock pad, and the electromechanical device is fixed through the bolts on two sides of the mounting plate; the support frame is located the below of mounting panel, and the spout has been seted up to the both sides of support frame to the mounting hole has all been seted up to the bottom both sides of support frame.
Furthermore, the first anti-seismic structure comprises a slide rail, an elastic rod, a slide seat, a connecting block A and a connecting block B, the slide rail is welded in the support frame, a limiting groove is formed in the slide rail, and the elastic rod is arranged in the limiting groove formed in the slide rail; the sliding seat is connected to the sliding rail in a sliding mode, the left side of the sliding seat is provided with a connecting block A, and the tail end of the connecting block B is rotatably connected with the head end of the connecting block A; the bottom of the sliding seat is provided with a bulge, and the bulge at the bottom of the sliding seat is in contact with one side of the elastic rod.
Furthermore, the first anti-seismic structure further comprises a connecting block C, a connecting block D, a sliding rod and a shock absorber, the tail end of the connecting block C is rotatably connected with the right end of the sliding seat, and the middle section of the connecting block C is rotatably connected with the head end of the connecting block B; the tail end of the connecting block D is rotatably connected with the head end of the connecting block C, and the head end of the connecting block D is welded with the bottom of the mounting plate; the sliding rod is welded at the joint between the connecting block C and the connecting block D and slides in sliding grooves formed in the two sides of the supporting frame; the shock absorber head end is connected with connecting block D, and the tail end of shock absorber is connected with the head end of connecting block C.
Furthermore, the second anti-vibration structure comprises a connecting seat, a connecting plate A, a right connecting block, a connecting plate B and a top connecting block, and the connecting seat is welded in the supporting frame; the tail end of the connecting plate A is rotatably connected with the right side of the connecting seat, and the head end of the connecting plate A is rotatably connected with the right connecting block; the tail end of the connecting plate B is rotatably connected with the right connecting block, the head end of the connecting plate B is rotatably connected with the right end of the top connecting block, and the top connecting block is connected with the bottom of the supporting frame in a welding mode.
Compared with the prior art, the utility model discloses following beneficial effect has:
first antidetonation structure and second antidetonation structure have been improved, can effectual decay the produced vibrations of support through the cooperation use, prevent to produce the harm to electromechanical device because of violent vibrations, specifically as follows: firstly, the sliding rail is welded in the support frame, a limiting groove is formed in the sliding rail, and the sliding rail is connected with a sliding seat in a sliding manner; the bulge at the bottom of the sliding seat is contacted with the elastic rod, when the mounting plate is impacted, the mounting plate is pressed downwards to bend the connecting block D, the pressure is transmitted to the shock absorber, then the sliding seat is made to slide on the sliding rail, the sliding seat is made to be contacted with the elastic rod, and the sliding seat is made to rebound through the elasticity of the elastic rod, so that the shock is attenuated, and an effective shock absorption effect can be performed on the electromechanical equipment; second, when receiving the impact, the bottom welding because of top connecting block and support frame links to each other, thereby make connecting plate A, connecting plate B, connecting plate C and connecting plate D extend to both sides, and the antidetonation spring welds at right connecting block and left connecting block, and right connecting block and left connecting block slide to both sides on the gag lever post, thereby formed a bradyseism structure, use through the cooperation with first antidetonation structure, decay vibrations that can be quick, thereby can prevent to cause the damage to electromechanical device because of violent vibrations.
Drawings
Fig. 1 is a schematic axial view of the present invention.
Fig. 2 is a schematic view of the internal structure of the support frame of the present invention.
Fig. 3 is a schematic structural view of a first earthquake-proof structure of the present invention.
Fig. 4 is a schematic view of a split structure of the first earthquake-proof structure of the present invention.
Fig. 5 is a schematic view of a second earthquake resistant structure of the present invention.
In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:
1. an electromechanical device; 101. mounting a plate; 102. a shock pad; 103. a bolt; 104. a support frame; 105. a chute; 106. mounting holes; 2. a first seismic structure; 201. a slide rail; 202. an elastic rod; 203. a sliding seat; 204. connecting a block A; 205. connecting block B; 206. connecting blocks C; 207. connecting a block D; 208. a slide bar; 209. a shock absorber; 3. a second seismic resistant structure; 301. a connecting seat; 302. a connecting plate A; 303. a right connecting block; 304. a connecting plate B; 305. a top connecting block; 306. connecting plates C; 307. a left connecting block; 308. a connecting plate D; 309. an anti-seismic spring; 310. a limiting rod.
Detailed Description
The following describes embodiments of the present invention in further detail with reference to the accompanying drawings and examples. The following examples are intended to illustrate the invention, but are not intended to limit the scope of the invention.
In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are merely for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.
In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.
Example (b):
as shown in figures 1 to 5:
the utility model provides an anti-seismic support of electromechanical equipment in a building, which comprises electromechanical equipment 1; four groups of first anti-seismic structures 2 are mounted at the bottom of the electromechanical device 1, and a second anti-seismic structure 3 is further mounted at the bottom of the electromechanical device 1; the second anti-seismic structure 3 comprises a connecting plate C306, a left connecting block 307, a connecting plate D308, an anti-seismic spring 309 and a limiting rod 310, the tail end of the connecting plate C306 is rotatably connected with the left side of the connecting seat 301, and the head end of the connecting plate C306 is rotatably connected with the left connecting block 307; the tail end of the connecting plate D308 is rotatably connected with the left connecting block 307; antidetonation spring 309 welds between right connecting block 303 and left connecting block 307, and gag lever post 310 sliding connection is in right connecting block 303 and left connecting block 307, when receiving the impact, because of the bottom welding of top connecting block 305 with support frame 104 links to each other, thereby make connecting plate A302, connecting plate B304, connecting plate C306 and connecting plate D308 extend to both sides, and antidetonation spring 309 welds at right connecting block 303 and left connecting block 307, and right connecting block 303 and left connecting block 307 slide to both sides on gag lever post 310, thereby a bradyseism structure has been formed, use through the cooperation with first antidetonation structure 2, the decay vibrations that can be quick, thereby can prevent to cause the damage to electromechanical device 1 because of violent vibrations.
Referring to fig. 1, the electromechanical device 1 includes a mounting plate 101, a shock pad 102, a bolt 103, a support bracket 104, a sliding groove 105, and a mounting hole 106, the shock pad 102 is disposed on the mounting plate 101, the electromechanical device 1 is placed on the shock pad 102, and the electromechanical device 1 is fixed by the bolt 103 on both sides of the mounting plate 101; the supporting frame 104 is located below the mounting plate 101, and two sides of the supporting frame 104 are provided with sliding grooves 105, and two sides of the bottom of the supporting frame 104 are provided with mounting holes 106.
Referring to fig. 4, the first anti-seismic structure 2 includes a sliding rail 201, an elastic rod 202, a sliding seat 203, a connecting block a204, and a connecting block B205, the sliding rail 201 is welded in the supporting frame 104, a limiting groove is formed on the sliding rail 201, and the elastic rod 202 is arranged in the limiting groove formed on the sliding rail 201; the sliding seat 203 is connected to the sliding rail 201 in a sliding manner, a connecting block A204 is arranged on the left side of the sliding seat 203, and the tail end of the connecting block B205 is rotatably connected with the head end of the connecting block A204; the bottom of the sliding seat 203 is provided with a protrusion, and the protrusion at the bottom of the sliding seat 203 contacts with one side of the elastic rod 202.
Referring to fig. 3, the first anti-seismic structure 2 further includes a connecting block C206, a connecting block D207, a sliding rod 208 and a shock absorber 209, the tail end of the connecting block C206 is rotatably connected with the right end of the sliding seat 203, and the middle position of the connecting block C206 is rotatably connected with the head end of the connecting block B205; the tail end of the connecting block D207 is rotatably connected with the head end of the connecting block C206, and the head end of the connecting block D207 is welded with the bottom of the mounting plate 101; the sliding rod 208 is welded at the joint between the connecting block C206 and the connecting block D207, and the sliding rod 208 slides in the sliding grooves 105 formed in the two sides of the supporting frame 104; the head end of the shock absorber 209 is connected with the connecting block D207, and the tail end of the shock absorber 209 is connected with the head end of the connecting block C206, because the sliding rail 201 is welded in the supporting frame 104, the sliding rail 201 is provided with a limiting groove, and the sliding rail 201 is connected with the sliding seat 203 in a sliding manner; the protruding and elastic rod 202 of sliding seat 203 bottom contact, and mounting panel 101 pushes down when receiving the impact and makes connecting block D207 crooked, and pressure passes to on the bumper shock absorber 209, then makes sliding seat 203 on slide rail 201 with slide, makes sliding seat 203 and elastic rod 202 contact, makes sliding seat 203 kick-back through the elasticity of elastic rod 202 to the damping vibrations, and then can carry out an effectual bradyseism effect to electromechanical device 1.
Referring to fig. 5, the second earthquake-resistant structure 3 comprises a connecting seat 301, a connecting plate a302, a right connecting block 303, a connecting plate B304 and a top connecting block 305, wherein the connecting seat 301 is welded in the supporting frame 104; the tail end of the connecting plate A302 is rotatably connected with the right side of the connecting seat 301, and the head end of the connecting plate A302 is rotatably connected with the right connecting block 303; the tail end of the connecting plate B304 is rotatably connected with the right connecting block 303, the head end of the connecting plate B304 is rotatably connected with the right end of the top connecting block 305, and the top connecting block 305 is connected with the bottom of the supporting frame 104 in a welding mode.
The specific use mode and function of the embodiment are as follows:
when the anti-seismic device is used, the first anti-seismic structure 2 and the second anti-seismic structure 3 are matched, firstly, the sliding rail 201 is welded in the support frame 104, a limiting groove is formed in the sliding rail 201, and the sliding rail 201 is connected with the sliding seat 203 in a sliding manner; the bulge at the bottom of the sliding seat 203 is in contact with the elastic rod 202, when the mounting plate 101 is impacted, the connecting block D207 is bent by pressing downwards, the pressure is transmitted to the shock absorber 209, then the sliding seat 203 slides on the sliding rail 201, the sliding seat 203 is in contact with the elastic rod 202, the sliding seat 203 rebounds through the elasticity of the elastic rod 202, the shock is attenuated, and an effective shock absorption effect can be further performed on the electromechanical device 1; secondly, when receiving the impact, because of the bottom welded connection of top connecting block 305 with support frame 104, thereby make connecting plate A302, connecting plate B304, connecting plate C306 and connecting plate D308 extend to both sides, and antidetonation spring 309 welds at right connecting block 303 and left connecting block 307, and right connecting block 303 and left connecting block 307 slide to both sides on gag lever post 310, thereby formed a bradyseism structure, use through the cooperation with first antidetonation structure 2, the decay that can be quick shakes, thereby can prevent to cause the damage to electromechanical device 1 because of violent vibrations.
The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.