CN115464567B - Steel construction surface rust cleaning device - Google Patents

Abstract

The invention relates to the technical field of rust removal of steel surfaces, in particular to a steel structure surface rust removal device. The invention provides a steel structure surface rust removing device for closed rust removal. A rust removing device for the surface of a steel structure comprises a mounting plate frame, a placing frame, a transparent isolation shell, a sand blower, a separating mechanism and the like; the upper side is connected with transparent isolation shell in the installation grillage, and the downside is connected with the frame of placing in the transparent isolation shell, installs the sandblast between installation grillage and the transparent isolation shell, and the quartz sand of blowout is derusted to rusty steel construction after the sandblast starts, and installation grillage downside is equipped with separating mechanism, and separating mechanism is used for separating ferric oxide and quartz sand. According to the invention, the opening and closing door is manually rotated by people, then, the rigid mechanism requiring rust removal is placed on the top of the placement frame, and after the placement is completed, the opening and closing door is manually rotated reversely by people and the sand blaster is started, so that the closed rust removal effect is realized, and dust flying to pollute the environment is avoided.

Description

Steel construction surface rust cleaning device

Technical Field

The invention relates to the technical field of rust removal of steel surfaces, in particular to a steel structure surface rust removal device.

Background

The steel structure comprises steel material, and at steel structure storage's in-process, moist air, soil and environment all make steel structure surface rust easily, and rusty steel material can influence steel structure's surface function, so, people can use rust cleaning device to rust cleaning to rusty steel material, and current rust cleaning device adopts the emery wheel of polishing to rust cleaning generally, in rust cleaning's in-process, causes impurity to drift easily to cause the pollution to the environment, so, need design a rust cleaning device.

The patent application number CN111843788B discloses a steel rust cleaning device for building engineering, can change the distance between two steel fixture through adjusting movable bracket, thereby hold in the palm the steel of different width through two steel fixture and put, start the back with actuating mechanism, actuating mechanism can drive pushing mechanism and rust cleaning mechanism in step and work, adjust rust cleaning mechanism to with wait to rust cleaning steel's top surface contact, the steel that holds in the palm and put between two steel fixture is under pushing mechanism's promotion horizontal movement, make steel top surface's different positions with rust cleaning mechanism contact, thereby carry out rust cleaning treatment to rust cleaning mechanism, this rust cleaning device carries out rust cleaning to steel through rust cleaning mechanism, but this rust cleaning device adopts open rust cleaning, just so lead to the dust to fly upward polluted environment easily.

The steel structure surface rust removing device with the closed rust removing function is designed to achieve the effect of overcoming the defect that the existing rust removing device adopts open rust removing to easily cause dust to pollute the environment.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides a closed rust-removing steel structure surface rust-removing device, which aims to overcome the defect that the existing rust-removing device adopts open rust removal and is easy to cause dust pollution to the environment.

In order to achieve the above object, the present invention is realized by the following scheme: the utility model provides a steel construction surface rust cleaning device, includes:

the transparent isolation shell is connected to the upper side in the installation plate frame;

the lower side of the transparent isolation shell is connected with the placing rack;

the left side and the right side of the front part of the transparent isolation shell are symmetrically hinged with the opening and closing door;

the sand blaster is arranged between the mounting plate frame and the transparent isolation shell, and after the sand blaster is started, quartz sand is sprayed out to rust the rusted steel structure;

the separating mechanism is arranged at the lower side of the mounting plate frame and is used for separating ferric oxide and quartz sand;

the adsorption mechanism is arranged at the lower side of the front part of the mounting plate frame and used for adsorbing and collecting ferric oxide.

As an improvement of the scheme, the bottom of the placement frame is connected with a grid frame.

As an improvement of the above scheme, the separating mechanism comprises:

the limiting plate frame is connected with the lower side in the installation plate frame;

the servo motor is arranged on the left side of the mounting plate frame;

the storage hopper is connected with the lower side in the limiting plate frame in a sliding manner;

the first electromagnet is rotationally connected with the first electromagnet used for adsorbing the ferric oxide in the limiting plate frame, and an output shaft of the servo motor is connected with the first electromagnet.

As an improvement of the above scheme, the adsorption mechanism comprises:

the lower side of the front part of the mounting plate frame is connected with a support frame;

the left side of the support frame is provided with an air cylinder;

the right side of the support frame is connected with a first telescopic rod;

the telescopic rod of the cylinder is connected with a second electromagnet used for magnetically attracting the ferric oxide, the second electromagnet is connected with the limiting plate frame in a sliding mode, and the second electromagnet is connected with the first telescopic rod.

As the improvement of above-mentioned scheme, still including the centralization mechanism that drives ferric oxide and quartz sand and concentrate whereabouts, centralization mechanism includes:

the top of the limiting plate frame is connected with a guide plate frame;

the roller is rotatably connected with the lower side in the guide plate frame.

As an improvement of the above scheme, the device further comprises a collecting mechanism for collecting ferric oxide, wherein the collecting mechanism comprises:

the collecting box is connected to the lower side of the rear part of the mounting plate frame;

the dust collector is arranged in the middle of the top of the collecting box;

the left part and the right part of the dust collector are communicated with the flow guide pipe;

the suction frame is connected with the lower side of the front part of the limiting plate frame, the guide pipe on the left side is communicated with the left part of the suction frame, and the guide pipe on the right side is communicated with the right part of the suction frame.

As the improvement of above-mentioned scheme, still include the shake of useful Yu Zhenping deposit quartz sand in the fill and level the mechanism, shake the mechanism and include:

the left side and the right side of the front part of the second electromagnet are connected with the connecting frame;

the rear sides of the two connecting frames are connected with the sliding rods in a sliding manner;

the inner sides of the two sliding rods are connected with the first ejector blocks;

the left and right parts of the limiting plate frame are connected with the toothed top plate, the first top block on the left side is connected with the toothed top plate on the left side in a sliding manner, and the first top block on the right side is connected with the toothed top plate on the right side in a sliding manner;

the connecting frame is connected with the first spring, and the first spring winds on the slide bar.

As the improvement of above-mentioned scheme, still including being used for opening the trigger mechanism of cylinder and second electro-magnet voluntarily, trigger mechanism includes:

the upper side of the left part of the first electromagnet is connected with a second jacking block;

the rear side of the left part of the limiting plate frame is connected with a second telescopic rod;

the rear part of the second telescopic rod is connected with a top frame;

the switch is arranged at the rear side of the left part of the limiting plate frame and is electrically connected with the cylinder and the second electromagnet;

the second spring is connected between the front part of the top frame and the second telescopic rod, and the second spring is wound on the second telescopic rod.

The invention has the advantages that: 1. according to the invention, the opening and closing door is manually rotated by people, then, a rigid mechanism needing rust removal is placed on the top of the placement frame by people, and after the placement is completed, the opening and closing door is manually rotated reversely by people and the sand blaster is started, so that the closed rust removal effect is realized, and dust is prevented from flying to pollute the environment;

2. the dust collector is started by people, so that the dust collector sucks ferric oxide in the suction frame into the collecting box through the guide pipe, when the ferric oxide in the collecting box reaches a certain amount, the collecting box is opened by people to collect the ferric oxide, and therefore the collecting effect is achieved, and the subsequent recovery is convenient;

3. when the second top block is far away from the top frame, the second spring resets to drive the top frame to move forwards to reset and keep away from the switch, and the second telescopic rod shortens, so that the air cylinder and the second electromagnet are opened, and the automatic opening effect is realized.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic perspective view of a first part of the present invention.

Fig. 3 is a schematic perspective view of a second part of the present invention.

Fig. 4 is a schematic perspective view of a third portion of the present invention.

Fig. 5 is a schematic perspective view of a fourth part of the present invention.

Fig. 6 is a schematic perspective view of a first part of the separation mechanism of the present invention.

Fig. 7 is a schematic perspective view of a second part of the separation mechanism of the present invention.

Fig. 8 is a schematic perspective view of a first part of the adsorption mechanism according to the present invention.

Fig. 9 is a schematic perspective view of a second part of the adsorption mechanism of the present invention.

Fig. 10 is a schematic perspective view of a third part of the adsorption mechanism of the present invention.

Fig. 11 is a schematic perspective view of a first part of the focusing mechanism of the present invention.

Fig. 12 is a schematic perspective view of a second part of the focusing mechanism of the present invention.

Fig. 13 is a schematic perspective view of a third part of the centralizing mechanism according to the present invention.

Fig. 14 is a schematic perspective view of a first part of the collecting mechanism according to the present invention.

Fig. 15 is a schematic perspective view of a second part of the collecting mechanism of the present invention.

Fig. 16 is a schematic perspective view of a third part of the collecting mechanism according to the present invention.

Fig. 17 is a schematic perspective view of a first part of the shake leveling mechanism according to the invention.

Fig. 18 is a schematic perspective view of a second part of the shake leveling mechanism according to the invention.

Fig. 19 is a schematic perspective view of a first part of the trigger mechanism of the present invention.

Fig. 20 is an enlarged view at a of the present invention.

Fig. 21 is a schematic perspective view of a second portion of the trigger mechanism of the present invention.

Wherein the above figures include the following reference numerals: 1. mounting rack, 11, placement rack, 2, transparent isolation housing, 21, opening and closing door, 3, sand blaster, 4, separating mechanism, 41, limiting rack, 42, servo motor, 43, storage bucket, 44, first electromagnet, 5, adsorption mechanism, 51, support rack, 52, cylinder, 53, first telescopic link, 54, second electromagnet, 6, centralizing mechanism, 61, guide rack, 62, roller, 7, collecting mechanism, 71, collecting box, 72, honeycomb duct, 73, suction rack, 74, dust collector, 8, shake leveling mechanism, 81, connecting rack, 82, toothed roof, 83, slide bar, 84, first spring, 85, first ejector block, 9, triggering mechanism, 91, ejector rack, 92, switch, 93, second telescopic link, 94, second spring, 95, second ejector block.

Detailed Description

The invention will be further described with reference to the accompanying drawings and detailed description below:

example 1

Referring now to fig. 1-5, a steel structure surface rust removing device comprises a mounting plate frame 1, a placing frame 11, a transparent isolation shell 2, an opening and closing door 21, a sand blaster 3, a separating mechanism 4 and an adsorption mechanism 5, wherein the upper side in the mounting plate frame 1 is connected with the transparent isolation shell 2, the placing frame 11 is welded on the lower side in the transparent isolation shell 2, the bottom of the placing frame 11 is connected with a grid frame, the left side and the right side of the front part of the transparent isolation shell 2 are symmetrically hinged with the opening and closing door 21, the sand blaster 3 is arranged between the mounting plate frame 1 and the transparent isolation shell 2, the separating mechanism 4 is arranged on the lower side of the mounting plate frame 1, and the adsorption mechanism 5 is arranged on the lower side of the front part of the mounting plate frame 1.

Referring to fig. 1, 5, 6 and 7, the separating mechanism 4 includes a limiting plate frame 41, a servo motor 42, a storage hopper 43 and a first electromagnet 44, the lower side in the mounting plate frame 1 is connected with the limiting plate frame 41, the servo motor 42 is fixedly connected with the left side of the mounting plate frame 1 through bolts, the lower side in the limiting plate frame 41 is slidably connected with the storage hopper 43, the first electromagnet 44 is rotatably connected in the limiting plate frame 41, and an output shaft of the servo motor 42 is connected with the first electromagnet 44.

Referring to fig. 1, 5, 8, 9 and 10, the adsorption mechanism 5 includes a support frame 51, an air cylinder 52, a first telescopic rod 53 and a second electromagnet 54, the support frame 51 is welded at the lower side of the front part of the installation plate frame 1, the air cylinder 52 is fixedly connected to the left side of the support frame 51 through bolts, the first telescopic rod 53 is connected to the right side of the support frame 51, the second electromagnet 54 is connected to the telescopic rod of the air cylinder 52, the second electromagnet 54 is slidably connected with the limiting plate frame 41, and the second electromagnet 54 is connected with the first telescopic rod 53.

When people need to rust the steel structure, people can use the steel structure surface rust removing device, firstly, people pour a proper amount of quartz sand into the sand blaster 3, then people manually rotate the opening and closing door 21, after the transparent isolation shell 2 is opened, people place the steel structure needing to be rust removed at the top of the placement frame 11, after the placement is completed, people manually reversely rotate the opening and closing door 21, after the opening and closing door 21 closes the transparent isolation shell 2, people can start the sand blaster 3 and the first electromagnet 44, so that the sand blaster 3 sprays the quartz sand onto the steel structure, iron oxide on the steel structure is removed, people can check the rust removing condition of the steel structure through the transparent isolation shell 2, then the iron oxide and the quartz sand fall downwards through a grid frame at the bottom of the placement frame 11, when the quartz sand falls downwards to be contacted with the first electromagnet 44, the quartz sand falls downwards into the storage hopper 43 along the first electromagnet 44, when the ferric oxide falls downwards to be in contact with the first electromagnet 44, the first electromagnet 44 attracts the ferric oxide, when rust removal is finished, people can close the sand blaster 3 and open the air cylinder 52 and the second electromagnet 54, so that the telescopic rod of the air cylinder 52 stretches backwards to drive the second electromagnet 54 to move backwards, the first telescopic rod 53 stretches, when the second electromagnet 54 moves backwards to a proper position, people close the air cylinder 52 and start the servo motor 42, the output shaft of the servo motor 42 rotates to drive the first electromagnet 44 to rotate, when the first electromagnet 44 rotates, the second electromagnet 54 attracts the ferric oxide on the first electromagnet 44 because the magnetic force of the second electromagnet 54 is larger than that of the first electromagnet 44, thereby realizing the classified collection effect, facilitating the subsequent recovery, the servo motor 42 is turned off, then, the air cylinder 52 is started, the telescopic rod of the air cylinder 52 is shortened forwards to drive the second electromagnet 54 to move forwards, the first telescopic rod 53 is shortened, when the second electromagnet 54 moves forwards to a proper position, the second electromagnet 54 and the air cylinder 52 are turned off, the second electromagnet 54 does not have magnetic force, so that the iron oxide falls downwards, the iron oxide can be collected on the lower side of the front part of the limiting plate frame 41, then, the opening and closing door 21 is manually rotated according to the steps, after the transparent isolation shell 2 is opened, the rust-removed steel structure is taken out, then, the opening and closing door 21 is reversely rotated according to the steps, the storage hopper 43 is manually moved leftwards to a proper position, then, quartz sand in the storage hopper 43 is collected, and after the collection is completed, the storage hopper 43 is moved rightwards to a proper position.

Example 2

On the basis of embodiment 1, referring to fig. 1, 5, 11, 12 and 13, the device further comprises a centralizing mechanism 6, wherein the centralizing mechanism 6 comprises a guide plate frame 61 and a roller 62, the top of the limiting plate frame 41 is welded with the guide plate frame 61, the guide plate frame 61 is positioned at the lower side of the placing frame 11, and the roller 62 is rotatably connected to the lower side in the guide plate frame 61.

Referring now to fig. 1, 5, 14, 15 and 16, the device further comprises a collecting mechanism 7, the collecting mechanism 7 comprises a collecting box 71, a flow guide pipe 72, a suction frame 73 and a dust collector 74, the collecting box 71 is connected to the lower side of the rear portion of the mounting plate frame 1, the dust collector 74 is mounted in the middle of the top of the collecting box 71, the left and right portions of the dust collector 74 are communicated with the flow guide pipe 72, the suction frame 73 is welded to the lower side of the front portion of the limiting plate frame 41, the left flow guide pipe 72 is communicated with the left portion of the suction frame 73, and the right flow guide pipe 72 is communicated with the right portion of the suction frame 73.

Referring to fig. 1, 5, 17 and 18, the vibration leveling mechanism 8 further comprises a vibration leveling mechanism 8, the vibration leveling mechanism 8 comprises a connecting frame 81, a toothed top plate 82, a sliding rod 83, a first spring 84 and a first top block 85, the connecting frame 81 is welded on the left side and the right side of the front portion of the second electromagnet 54, the sliding rods 83 are connected on the rear sides of the two connecting frames 81 in a sliding mode, the first top blocks 85 are connected on the inner sides of the two sliding rods 83, the toothed top plate 82 is connected on the left and right sides of the limiting plate frame 41 in a sliding mode, the first top block 85 on the left side is connected with the toothed top plate 82 on the left side in a sliding mode, the first top block 85 on the right side is connected with the toothed top plate 82 on the right side in a sliding mode, the first spring 84 is connected between the sliding rod 83 on the left side and the connecting frame 81 on the right side, and the first spring 84 is wound on the sliding rod 83.

Referring now to fig. 1, 5, 19, 20 and 21, the device further comprises a triggering mechanism 9, the triggering mechanism 9 comprises a top frame 91, a switch 92, a second telescopic rod 93, a second spring 94 and a second top block 95, the second top block 95 is connected to the upper left side of the first electromagnet 44, the second telescopic rod 93 is connected to the rear left side of the limiting plate frame 41, the top frame 91 is welded to the rear of the second telescopic rod 93, the top frame 91 is in contact with the second top block 95, the switch 92 is mounted to the rear left side of the limiting plate frame 41, the switch 92 is in contact with the air cylinder 52 and the second electromagnet 54 through electrical connection, the second spring 94 is connected between the front of the top frame 91 and the second telescopic rod 93, and the second spring 94 is wound on the second telescopic rod 93.

The iron oxide and the quartz sand drop down into the guide plate frame 61 through the placement frame 11, when the iron oxide and the quartz sand drop down into contact with the roller 62, the roller 62 rotates, and then the iron oxide and the quartz sand drop down into contact with the first electromagnet 44 through the guide plate frame 61 and the roller 62 in a concentrated manner, thereby achieving a concentrated effect and avoiding the iron oxide from being adsorbed.

When the second electromagnet 54 is turned off, the iron oxide on the second electromagnet 54 falls down into the suction frame 73, when the iron oxide in the suction frame 73 reaches a certain amount, people can start the dust collector 74, so that the iron oxide in the suction frame 73 is sucked into the collecting box 71 through the guide pipe 72, the collecting effect is achieved, after the iron oxide in the suction frame 73 is collected, people can turn off the dust collector 74, when the iron oxide in the collecting box 71 reaches a certain amount, people turn on the collecting box 71, then collect the iron oxide, and after the collecting is completed, people turn off the collecting box 71.

The second electromagnet 54 moves back and forth to drive the connecting frame 81 to move back and forth, so that the sliding rod 83 and the first top block 85 move back and forth, when the first top block 85 moves back and forth to be in contact with the convex part of the corrugated roof 82, the first top block 85 moves outwards adaptively, so that the sliding rod 83 moves outwards, the first spring 84 is stretched, when the first top block 85 moves back and forth to be in contact with the concave part of the corrugated roof 82, the first spring 84 resets to drive the sliding rod 83 to move inwards, so that the first top block 85 moves inwards, the limiting plate frame 41 and the storage hopper 43 vibrate through the first top block 85, and quartz sand in the storage hopper 43 is leveled.

The second telescopic rod 93 is in an elongation state in the initial state, the second spring 94 is stretched, the first electromagnet 44 rotates to drive the second top block 95 to rotate, when the second top block 95 rotates to be far away from the top frame 91, the second spring 94 resets to drive the top frame 91 to move forwards to be far away from the switch 92, so that the second telescopic rod 93 is shortened, the air cylinder 52 and the second electromagnet 54 are opened, and then the telescopic rod of the air cylinder 52 is stretched backwards to be closed after being in a proper position, so that the effect of automatic opening is achieved, when the second top block 95 rotates to be in contact with the top frame 91, the second top block 95 drives the top frame 91 to move backwards, so that the second telescopic rod 93 is stretched, the second spring 94 is stretched, when the top frame 91 moves backwards to be in contact with the switch 92, the air cylinder 52 is started, the telescopic rod of the air cylinder 52 is shortened forwards to drive the second electromagnet 54 to move backwards, and when the telescopic rod of the air cylinder 52 is shortened forwards to be in an initial position, the air cylinder 52 and the second electromagnet 54 is closed.

It will be apparent to those skilled in the art from this disclosure that various other changes and modifications can be made which are within the scope of the invention as defined in the appended claims.

Claims (2)

1. The utility model provides a steel construction surface rust cleaning device which characterized in that includes:

the transparent isolation device comprises a mounting plate frame (1) and a transparent isolation shell (2), wherein the transparent isolation shell (2) is connected to the upper side in the mounting plate frame (1);

the lower side of the transparent isolation shell (2) is connected with the placement frame (11);

the left side and the right side of the front part of the transparent isolation shell (2) are symmetrically hinged with the opening and closing door (21);

the sand blaster (3) is arranged between the mounting plate frame (1) and the transparent isolation shell (2), and quartz sand is sprayed out to rust a rusted steel structure after the sand blaster (3) is started;

the separating mechanism (4) is arranged at the lower side of the installation plate frame (1), and the separating mechanism (4) is used for separating ferric oxide and quartz sand;

the adsorption mechanism (5) is arranged at the lower side of the front part of the installation plate frame (1), and the adsorption mechanism (5) is used for adsorbing and collecting ferric oxide;

the separating mechanism (4) comprises: the bottom of the placement frame (11) is connected with a grid rack;

the separating mechanism (4) comprises:

the limiting plate frame (41) is connected with the lower side in the installation plate frame (1);

a servo motor (42) is arranged on the left side of the installation plate frame (1);

a storage bucket (43), wherein the storage bucket (43) is connected to the lower side of the limiting plate frame (41) in a sliding manner;

the first electromagnet (44) is rotationally connected with the first electromagnet (44) for adsorbing the ferric oxide in the limiting plate frame (41), and an output shaft of the servo motor (42) is connected with the first electromagnet (44);

the adsorption mechanism (5) comprises:

the lower side of the front part of the mounting plate frame (1) is connected with the support frame (51);

the cylinder (52) is arranged on the left side of the supporting frame (51);

the right side of the supporting frame (51) is connected with a first telescopic rod (53);

the telescopic rod of the air cylinder (52) is connected with a second electromagnet (54) for magnetically attracting ferric oxide, the second electromagnet (54) is connected with the limiting plate frame (41) in a sliding mode, and the second electromagnet (54) is connected with the first telescopic rod (53);

the device also comprises a centralizing mechanism (6) for driving the ferric oxide and the quartz sand to centralize and fall, and the centralizing mechanism (6) comprises:

the top of the limiting plate frame (41) is connected with the guide plate frame (61);

a roller (62), the lower side in the guide plate frame (61) is rotatably connected with the roller (62);

the device also comprises a collecting mechanism (7) for collecting the ferric oxide, wherein the collecting mechanism (7) comprises:

the collecting box (71) is connected with the lower side of the rear part of the mounting plate frame (1);

a dust collector (74), wherein the dust collector (74) is arranged in the middle of the top of the collecting box (71);

a flow guide pipe (72), wherein the left part and the right part of the dust collector (74) are communicated with the flow guide pipe (72);

the suction frame (73) is connected with the lower side of the front part of the limiting plate frame (41), the left flow guide pipe (72) is communicated with the left part of the suction frame (73), and the right flow guide pipe (72) is communicated with the right part of the suction frame (73);

still including being used for shaking the shake flat mechanism (8) of quartz sand in flat storage bucket (43), shake flat mechanism (8) including:

the connecting frame (81) is connected with the left side and the right side of the front part of the second electromagnet (54);

the rear sides of the two connecting frames (81) are connected with the sliding rods (83) in a sliding manner;

the inner sides of the two sliding rods (83) are connected with the first top blocks (85);

the left and right parts of the limiting plate frame (41) are connected with the toothed top plate (82), a left first top block (85) is connected with the left toothed top plate (82) in a sliding mode, and a right first top block (85) is connected with the right toothed top plate (82) in a sliding mode;

the connecting frame comprises a first spring (84), wherein the first spring (84) is connected between a left sliding rod (83) and a left connecting frame (81), the first spring (84) is connected between a right sliding rod (83) and a right connecting frame (81), and the first spring (84) is wound on the sliding rod (83).

2. A steel structure surface rust removing device according to claim 1, further comprising a trigger mechanism (9) for automatically opening the cylinder (52) and the second electromagnet (54), the trigger mechanism (9) comprising:

the second top block (95) is connected with the upper side of the left part of the first electromagnet (44);

the second telescopic rod (93) is connected with the rear side of the left part of the limiting plate frame (41);

the top frame (91) is connected with the rear part of the second telescopic rod (93);

the switch (92) is arranged at the rear side of the left part of the limiting plate frame (41), and the switch (92) is electrically connected with the air cylinder (52) and the second electromagnet (54);

and a second spring (94), wherein the second spring (94) is connected between the front part of the top frame (91) and the second telescopic rod (93), and the second spring (94) is wound on the second telescopic rod (93).