CN216643582U - Electromechanical engineering antidetonation support that security is high - Google Patents

Abstract

The utility model relates to the technical field of electromechanical engineering, in particular to an electromechanical engineering anti-seismic support with high safety, which comprises a base, wherein the upper end of the base is respectively connected with a shock absorption seat through a left-right symmetrical spring I, and the middle part of the upper end of the base is connected with the bottom end of a box body through a fixedly installed support plate; the number of the shock absorption seats is two, a support frame body is installed at the upper end of each shock absorption seat, an anti-corrosion layer is coated on the outer surface of the support frame body, the shock absorption seats upwards penetrate through the box body and are connected with the bottom end of the installation plate, and each shock absorption seat is correspondingly provided with a buffering shock absorption mechanism; the anti-seismic support has the advantages that the anti-seismic support has good strength and corrosion resistance, the anti-seismic support is prevented from being damaged by corrosion and fracture, and the safety performance of the anti-seismic support is improved.

Description

Electromechanical engineering antidetonation support that security is high

Technical Field

The utility model relates to the technical field of electromechanical engineering, in particular to an electromechanical engineering anti-seismic support with high safety.

Background

The electromechanical engineering comprises an electrical engineering technology, an automatic control and instrument, water supply and drainage, mechanical equipment installation, container installation, heat supply and ventilation and air conditioning engineering, building intelligent engineering, fire engineering, equipment and pipeline corrosion and heat insulation technology and the like.

Electromechanical device need use the antidetonation support when the installation, however current electromechanical engineering antidetonation support antidetonation effect is not good, and the antidetonation support prevents that fracture performance is relatively poor, leads to the antidetonation support when receiving the striking, the condition of fracture damage appears in the easy appearance, and the antidetonation support corrosion resisting property is relatively poor simultaneously, leads to the antidetonation support when using for a long time, the corrosion fracture appears in the easy appearance to greatly reduced the security performance of antidetonation support.

Disclosure of Invention

Aiming at the existing problems, the utility model provides an electromechanical engineering anti-seismic support with high safety.

In order to achieve the above object, the present invention adopts the following technical solutions:

an electromechanical engineering anti-seismic support with high safety comprises a base, wherein the periphery of the upper end of the base is respectively connected with a shock absorption seat through a corresponding first spring, and the middle part of the upper end of the base is connected with the bottom end of a box body through a fixedly installed supporting plate;

the number of the shock absorption seats is four, a support frame body is mounted at the upper end of each shock absorption seat, an anti-corrosion layer is coated on the outer surface of the support frame body, the shock absorption seats penetrate through the box body upwards and are connected with the bottom end of the mounting plate, and each shock absorption seat is correspondingly provided with a buffering shock absorption mechanism;

mounting holes are formed in the periphery of the mounting plate, the number of the mounting holes is four, a fixing rod is arranged in the middle of the bottom end of the mounting plate, and the bottom end of the fixing rod extends into the box body and is provided with a trapezoidal lug.

Preferably, buffering damper includes two connecting rods, and two connecting rods articulate both ends about the shock mount, and the other end of two connecting rods articulates respectively has slider one, slider one respectively with set up a spout sliding connection in the base upper end, through No. two spring coupling between one end and the spout of connecting rod are kept away from to slider one.

Preferably, the middle part of the bottom end of the inner wall of the box body is provided with a second sliding chute, and the second sliding chute is correspondingly connected with the second sliding block in a sliding manner; the two second sliding blocks are connected through a third spring and are correspondingly arranged at the bottom ends of the triangular blocks respectively; the inclined ends of the two triangular blocks are correspondingly matched with the trapezoidal lugs, the vertical ends of the two triangular blocks are respectively connected with a push rod, and the push rods are connected with anti-slip pads.

Preferably, the support frame body is made of titanium alloy, magnesium alloy and high manganese steel, the thicknesses of the titanium alloy and the magnesium alloy are the same, and the thicknesses of the titanium alloy and the magnesium alloy are smaller than that of the high manganese steel.

Preferably, the corrosion-resistant layer comprises fluorocarbon paint and epoxy resin paint, and the surface of the fluorocarbon paint is coated with the epoxy resin paint.

Due to the adoption of the technical scheme, the utility model has the beneficial effects that:

according to the utility model, equipment can be arranged on the mounting plate through the mounting hole, when the equipment is subjected to a shock force, the mounting plate drives the support frame body to extrude the first spring, the connecting rod downwards extrudes the first sliding block, the second spring is extruded, the impact force can be buffered, the equipment is prevented from being damaged, the mounting plate can not shake left and right through the box body, the support frame body plays a supporting role, meanwhile, the mounting plate is downwards stressed to drive the fixing rod and the trapezoidal lug to move downwards, the trapezoidal lug is matched with and extruded by the triangular blocks, the two triangular blocks are mutually far away, so that the push rod pushes the anti-skid pad to be in contact with the support frame body, and the effects of further damping, shock absorption and buffering are achieved; the support frame body that comprises titanium alloy, magnesium alloy, high manganese steel has guaranteed the intensity and the rigidity of support frame body, avoids the support frame body collision fracture damage to appear, and the corrosion resistant coating that comprises fluorocarbon coating and epoxy resin lacquer combination has high strength and corrosion resistance good advantage, prevents that the corrosion fracture damage from appearing in the support frame body, and the safety performance of support frame body has also been improved when increasing support frame body life to the mutually supporting of each part.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only for the present invention and protect some embodiments, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a schematic structural view of an electromechanical engineering seismic support with high safety according to the present invention;

FIG. 2 is a schematic structural view of the interior of the case of the present invention;

FIG. 3 is a cross-sectional view of the support frame body and corrosion-resistant layer of the present invention;

FIG. 4 is an enlarged cross-sectional view of the internal structure of the main body of the stand in accordance with the present invention;

FIG. 5 is an enlarged sectional view of the internal structure of the corrosion-resistant layer of the present invention;

in the figure: the novel shock absorber comprises a base 1, a sliding groove 2, a sliding groove 3, a spring II, a sliding block I4, a sliding block I5, a connecting rod 6, a shock absorption seat 7, a spring I8, a supporting plate 9, a corrosion-resistant layer 901, fluorocarbon paint 902, epoxy resin paint 11, a support frame body 111, titanium alloy 112, magnesium alloy 113, high manganese steel 12, a mounting hole 12, a box body 13, a fixing rod 14, a mounting plate 15, a trapezoidal bump 16, a triangular block 17, a push rod 18, a non-slip mat 19, a sliding block II 20, a sliding block III 21 and a sliding groove 22.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments of the present invention without any inventive step, are within the scope of the present invention.

Example 1

An electromechanical engineering anti-seismic support with high safety comprises a base 1, wherein the periphery of the upper end of the base 1 is respectively connected with a shock absorption seat 6 through a corresponding first spring 7, and the middle part of the upper end of the base 1 is connected with the bottom end of a box body 13 through a fixedly installed supporting plate 8;

the number of the shock absorption seats 6 is four, a support frame body 11 is mounted at the upper end of each shock absorption seat 6, the outer surface of each support frame body 11 is coated with an anti-corrosion layer 9, the shock absorption seats 6 penetrate through the box body 13 upwards and are connected with the bottom end of the mounting plate 15, and each shock absorption seat 6 is correspondingly provided with a buffering shock absorption mechanism;

mounting holes 12 have all been seted up around mounting panel 15, and the quantity of mounting hole 12 is four, and mounting panel 15 bottom mid-mounting has dead lever 14, and box 13 is stretched into to dead lever 14 bottom to install trapezoidal lug 16.

Buffering damper includes two connecting rods 5, and two connecting rods 5 articulate both ends about damper 6, and the other end of two connecting rods 5 articulates respectively has slider one 4, slider one 4 respectively with set up 2 sliding connection in the spout of 1 upper end of base, slider one 4 keep away from between connecting rod 5 one end and the spout 2 through No. two spring 3 connections.

A second sliding groove 22 is formed in the middle of the bottom end of the inner wall of the box body 13, and the second sliding groove 22 is correspondingly connected with the second two sliding blocks 20 in a sliding mode; the two second sliding blocks 20 are connected through a third spring 21, and the two second sliding blocks 20 are correspondingly arranged at the bottom ends of the triangular blocks 17 respectively; the inclined ends of the two triangular blocks 17 are correspondingly matched with the trapezoidal convex blocks 16, the vertical ends of the two triangular blocks 17 are respectively connected with a push rod 18, and the push rod 18 is connected with an anti-skid pad 19.

The support frame body 11 is composed of a titanium alloy 111, a magnesium alloy 112 and high manganese steel 113, the thicknesses of the titanium alloy 111 and the magnesium alloy 112 are the same, and the thicknesses of the titanium alloy 111 and the magnesium alloy 112 are smaller than that of the high manganese steel 113.

The corrosion-resistant layer 9 comprises fluorocarbon paint 901 and epoxy resin paint 902, and the surface of the fluorocarbon paint 901 is coated with the epoxy resin paint 902.

The working mode of the electromechanical engineering anti-seismic support with high safety is as follows:

when the device is used, the device can be installed on the installation plate 15 through the installation hole 12, when the device is subjected to a shock force, the installation plate 15 drives the support frame body 11 to extrude the first spring 7, the connecting rod 5 downwards extrudes the first slider 4, the second spring 3 is extruded, the impact force can be buffered, the device is prevented from being damaged, the box body 13 can prevent the installation plate 15 from shaking left and right, the support frame body 11 plays a supporting role, meanwhile, the installation plate 15 is stressed downwards to drive the fixing rod 14 and the trapezoidal lug 16 to move downwards, the trapezoidal lug 16 is matched with the triangular blocks 17 and extruded, the two triangular blocks 17 are far away from each other, the second slider 20 slides in the second sliding groove 22, so that the push rod 18 pushes the anti-skid pad 19 to be in contact with the support frame body 11, the effects of further damping and buffering are achieved, the support frame body 11 formed by the titanium alloy 111, the magnesium alloy 112 and the high manganese steel 113 ensures the strength and the rigidity of the support frame body 11, avoid support frame body 11 to appear collision fracture damage, the security performance of support frame body 11 has been improved, corrosion-resistant layer 9 that constitutes by fluorocarbon coating 901 and epoxy paint 902 combination has high strength and the good advantage of corrosion resistance, prevent that support frame body 11 from appearing corrosion fracture damage, the life of support frame body 11 has been increased, the security performance of support frame body 11 has been improved, thereby improve the security performance of electromechanical engineering antidetonation support, effectively solved current electromechanical engineering antidetonation support antidetonation effect not good, and intensity is not high, the problem of easy damage.

Titanium alloy, magnesium alloy, high manganese steel, epoxy paint, fluorocarbon coating that this patent adopted are the market, and its structure and control mode are prior art, no longer give unnecessary details in the description.

The above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (5)

1. The utility model provides a high electromechanical engineering antidetonation support of security, includes base (1), its characterized in that: the periphery of the upper end of the base (1) is respectively connected with a damping seat (6) through a corresponding first spring (7), and the middle part of the upper end of the base (1) is connected with the bottom end of the box body (13) through a fixedly installed supporting plate (8);

the number of the shock absorption seats (6) is four, a support frame body (11) is installed at the upper end of each shock absorption seat (6), the outer surface of each support frame body (11) is coated with a corrosion-resistant layer (9), the shock absorption seats (6) penetrate through the box body (13) upwards and are connected with the bottom end of the installation plate (15), and each shock absorption seat (6) is correspondingly provided with a buffering shock absorption mechanism;

mounting hole (12) have all been seted up all around mounting panel (15), and the quantity of mounting hole (12) is four, and mounting panel (15) bottom mid-mounting has dead lever (14), box (13) are stretched into to dead lever (14) bottom to install trapezoidal lug (16).

2. The electromechanical engineering anti-seismic support with high safety according to claim 1, is characterized in that: buffering damper includes two connecting rods (5), two connecting rod (5) articulate both ends about shock attenuation seat (6), and the other end of two connecting rods (5) articulates respectively has slider (4), slider (4) respectively with set up spout (2) sliding connection in base (1) upper end, the one end of connecting rod (5) is kept away from in slider (4) and be connected through No. two spring (3) between spout (2).

3. The electromechanical engineering anti-seismic support with high safety according to claim 1, is characterized in that: a second sliding groove (22) is formed in the middle of the bottom end of the inner wall of the box body (13), and the second sliding groove (22) is correspondingly connected with the second sliding blocks (20) in a sliding mode; the two second sliding blocks (20) are connected through a third spring (21), and the two second sliding blocks (20) are correspondingly arranged at the bottom ends of the triangular blocks (17) respectively; the inclined ends of the two triangular blocks (17) are correspondingly matched with the trapezoidal bumps (16), the vertical ends of the two triangular blocks (17) are respectively connected with a push rod (18), and the push rod (18) is connected with an anti-skid pad (19).

4. The electromechanical engineering anti-seismic support with high safety according to claim 1, is characterized in that: the support frame body (11) is composed of a titanium alloy (111), a magnesium alloy (112) and high manganese steel (113), the thicknesses of the titanium alloy (111) and the magnesium alloy (112) are the same, and the thicknesses of the titanium alloy (111) and the magnesium alloy (112) are smaller than that of the high manganese steel (113).

5. The electromechanical engineering anti-seismic support with high safety according to claim 1, is characterized in that: the corrosion-resistant layer (9) comprises fluorocarbon paint (901) and epoxy resin paint (902), and the surface of the fluorocarbon paint (901) is coated with the epoxy resin paint (902).

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