CN221870797U - Welding set is used in steel construction processing - Google Patents

Abstract

The utility model discloses a welding device for processing steel structures, comprising a bearing base; a driving cavity is provided inside the bearing base; and further comprising: a protective top plate is provided above the bearing base, and a welding gun head is fixedly provided at the center position of the bottom surface of the protective top plate; wherein the driving mechanism comprises a main bidirectional threaded rod, and the main bidirectional threaded rod is symmetrically installed on the front and rear sides of the driving cavity through bearings; wherein a positioning mechanism is provided above the driving cavity inside the bearing base, and the positioning mechanism comprises a positioning bracket. The welding device for processing steel structures, through the main bidirectional threaded rods distributed on the front and rear sides inside the bearing base and the secondary bidirectional threaded rods distributed in the front and rear directions, drives the positioning seat body to perform effective and convenient adjustments when positioning steel structures of different specifications, and the positioning seats on the front and rear sides of the positioning bracket drive the steel structure to slide inward synchronously, so as to perform welding work through the welding gun head.

Description

Welding device for steel structure processing

Technical Field

The utility model relates to the technical field of steel structure processing, in particular to a welding device for steel structure processing.

Background Art

Steel structure is a structure made of steel materials. It is one of the main types of building structures. It is mainly composed of steel beams, steel columns, steel trusses and other components made of steel and steel plates. It is widely used in large factories, venues, super high-rise buildings, bridges and other fields. Steel structures with different processing requirements need to be connected by welding and other means;

Publication No. CN220296224U discloses a welding device for processing steel structures. By setting a third motor, a third screw rod, a fourth screw rod and a clamping plate, the third motor drives the clamping plate to move relative to each other, so that the clamping plate clamps steel structures of different specifications. At the same time, the clamping plate base is installed at the output end of the second motor, so that two groups of steel structures to be processed are adjusted to different angles, thereby improving the compatibility of the welding device.

However, the above-mentioned welding device for steel structures still has the following problems during actual use: although the clamping pins are driven by symmetrically distributed screw rods to position the steel structure during welding, due to the differences in specifications of different types of steel structures, effective clamping of the steel structure cannot be achieved only by clamping in the front and rear directions. It is easy for the steel structure to be displaced in the up and down directions during docking and stress application. The same clamping mechanism on both sides cannot adjust the clamping force in a unified manner, which easily leads to deviations in the steel structures on both sides during welding.

Therefore we propose a welding device for steel structure processing, so as to solve the above-mentioned problems.

Utility Model Content

The purpose of the utility model is to provide a welding device for steel structure processing to solve the problem raised in the above-mentioned background technology that although the steel structure is currently positioned during welding by driving the clamping needles through symmetrically distributed screw rods, due to the differences in specifications of different types of steel structures, the effective clamping of the steel structure cannot be achieved only by clamping in the front and rear directions, and it is easy for the steel structure to be displaced in the up and down directions during docking and stress application. The same clamping mechanisms on both sides cannot adjust the clamping force in a unified manner, which easily leads to deviations in the steel structures on both sides during welding.

To achieve the above-mentioned purpose, the utility model provides the following technical solutions: A welding device for steel structure processing, comprising a bearing base, and supporting side plates fixedly mounted on the left and right sides of the bearing base;

A driving cavity is provided inside the bearing base, and a driving mechanism is provided in the driving cavity inside the bearing base;

It also includes: a protective top plate is arranged above the bearing base, and a welding gun head is fixedly arranged at the center position of the bottom surface of the protective top plate;

The driving mechanism includes a main bidirectional threaded rod, and the main bidirectional threaded rod is symmetrically installed on the front and rear sides of the driving cavity through bearings;

A positioning mechanism is arranged above the driving cavity inside the bearing base, and the positioning mechanism includes a positioning bracket, and the positioning bracket is symmetrically slidably arranged on the left and right sides above the bearing base.

Preferably, the top ends of the symmetrically arranged support side panels are fixedly connected to the outer ends of the bottom surface of the protective top plate, and feed slots are opened at the bottom of the symmetrically arranged support side panels, and the symmetrically arranged support side panels facilitate positioning and welding of steel structures of different specifications through the feed slots opened at the bottom.

Preferably, the right end of the main bidirectional threaded rod included in the driving mechanism is meshed and connected through a sprocket mechanism, and the left and right outer walls of the main bidirectional threaded rod on the front and rear sides are threadedly connected to the outer end of the guide slider, and the top ends of the left and right guide sliders are fixedly connected to the bottom end of the positioning bracket included in the positioning mechanism.

Preferably, the outer ends of the guide shafts are rotatably arranged on the front and rear sides of the top surface of the supporting base through bearings, and the left and right outer walls of the front and rear guide shafts are slidably arranged with main bevel gears, and the symmetrically arranged guide shafts are snap-connected with the main bevel gears through the protrusions on the outer walls.

Preferably, the positioning mechanism includes a secondary bidirectional threaded rod, and the secondary bidirectional threaded rod is rotatably arranged inside the positioning bracket through a bearing, and secondary bevel gears are fixedly arranged at the front and rear ends of the secondary bidirectional threaded rods on the left and right sides, and the secondary bevel gears are meshed and connected with the corresponding main bevel gears.

Preferably, the positioning mechanism includes a positioning seat body, and the bottom end of the positioning seat body is threadedly connected to the front and rear outer walls of the secondary bidirectional threaded rod, and the top surfaces of the symmetrically arranged positioning seat bodies are slidably provided with pressure slides, and the bottom surfaces of the pressure slides and the positioning seat body are connected to each other through a resistance spring.

Preferably, the outer sides of the symmetrically arranged positioning seat bodies are rotatably connected to the outer ends of the pressure contact plates through bearings, and the pressure contact plates and the positioning seat bodies are connected to each other through a return spring, and the pressure contact plates and the pressure slide plates are connected to each other through a traction rope.

Compared with the prior art, the beneficial effects of the utility model are as follows: the welding device for steel structure processing drives the positioning seat body to effectively and conveniently adjust the positioning of steel structures of different specifications through the main bidirectional threaded rods distributed on the front and rear sides of the bearing base and the secondary bidirectional threaded rods distributed in the front and rear directions, and the positioning seat bodies on the front and rear sides of the positioning bracket drive the steel structure to slide inward synchronously, so as to perform welding work through the welding gun head. The specific contents are as follows:

1. According to the different specifications of steel structures, the guide shafts set on the front and rear sides of the bearing base are rotated manually, and then the main bevel gear meshes with the secondary bevel gear and the secondary bidirectional threaded rod to rotate, so as to drive the positioning seat bodies threadedly connected on the front and rear sides to move, so as to adapt to the positioning of steel structures of different specifications;

2. The pressure plate is driven to slide downward by its weight, and then the pressure plate drives the traction rope to be tightened, and then the tightened traction rope drives the pressure contact plate fixedly connected at the top to flip downward, so that the pressure contact plate can cover the top of the steel structure, thereby preventing the steel structure from deflecting;

3. The main bidirectional threaded rod connected by the sprocket mechanism inside the rotation drive cavity rotates, so that the main bidirectional threaded rod drives the guide sliders connected by threads on the left and right sides and the positioning brackets on the top surface to move, and the positioning seats on the front and rear sides of the positioning brackets drive the steel structure to slide inward synchronously so that welding work can be performed through the welding gun head.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG1 is a schematic diagram of the overall three-dimensional structure of the utility model;

Figure 2 is a schematic diagram of the installation structure of the welding gun head of the utility model;

FIG3 is a schematic diagram of the installation structure of the main bidirectional threaded rod of the utility model;

FIG4 is a schematic diagram of the installation structure of the positioning bracket of the utility model;

FIG5 is an enlarged schematic diagram of the structure of point A in FIG4 of the present utility model;

FIG6 is a schematic diagram of the three-dimensional structure of the positioning seat body of the utility model;

FIG. 7 is a schematic diagram of the installation structure of the pressure slide plate and the pressure contact plate of the utility model.

In the figure: 1. bearing base; 2. supporting side plate; 3. driving cavity; 4. protective top plate; 5. feeding notch; 6. main two-way threaded rod; 7. positioning bracket; 8. sprocket mechanism; 9. guide slider; 10. guide shaft; 11. main bevel gear; 12. secondary two-way threaded rod; 13. secondary bevel gear; 14. positioning seat; 15. pressure slide plate; 16. resistance spring; 17. pressure resistance plate; 18. reset spring; 19. traction rope; 20. welding gun head.

DETAILED DESCRIPTION

The following will be combined with the drawings in the embodiments of the utility model to clearly and completely describe the technical solutions in the embodiments of the utility model. Obviously, the implementation regulations described are only part of the embodiments of the utility model, not all of the embodiments. Based on the embodiments of the utility model, all other embodiments obtained by ordinary technicians in this field without creative work are within the scope of protection of the utility model.

Please refer to Figures 1 to 7. The utility model provides the following technical solutions:

Embodiment 1: In order to solve the problem that the existing welding device is relatively cumbersome for positioning the steel structure, the present embodiment adopts the following technical scheme. According to the steel structure of different specifications, the guide shaft 10 arranged on the front and rear sides of the bearing base 1 is manually rotated, and then the meshing main bevel gear 11 meshes with the secondary bevel gear 13 and the secondary bidirectional threaded rod 12 to rotate, so as to drive the positioning seat body 14 threadedly connected on the front and rear sides to move, so as to adapt to the positioning of steel structures of different specifications;

A welding device for steel structure processing, comprising a bearing base 1; wherein a positioning mechanism is arranged above a driving cavity 3 inside the bearing base 1, and the positioning mechanism comprises a positioning bracket 7, and the positioning bracket 7 is symmetrically slidably arranged on the left and right sides above the bearing base 1;

The outer ends of the guide shafts 10 are rotatably arranged on the front and rear sides of the top surface of the bearing base 1 through bearings, and the left and right outer walls of the guide shafts 10 on the front and rear sides are slidably arranged with main bevel gears 11, and the symmetrically arranged guide shafts 10 are engaged and connected with the main bevel gears 11 through the protrusions on the outer walls;

The positioning mechanism includes a pair of bidirectional threaded rods 12, and the pair of bidirectional threaded rods 12 is rotatably arranged inside the positioning bracket 7 through a bearing, and the front and rear ends of the left and right side pair of bidirectional threaded rods 12 are fixedly provided with pair of bevel gears 13, and the pair of bevel gears 13 and the corresponding main bevel gears 11 are meshed and connected with each other; the positioning mechanism includes a positioning seat body 14, and the bottom end of the positioning seat body 14 is threadedly connected to the front and rear outer walls of the pair of bidirectional threaded rods 12;

As shown in Figures 3 to 5, according to steel structures of different specifications, the guide shaft 10 installed by a bearing on any one side of the top surface of the supporting base 1 is artificially rotated, so that the guide shaft 10 drives the main bevel gear 11 engaged by the protrusion on the outer wall to rotate, and the main bevel gear 11 drives the corresponding meshing connected secondary bevel gear 13 to rotate, and at the same time, the secondary bevel gear 13 drives the fixedly connected secondary bidirectional threaded rod 12 to rotate inside the positioning bracket 7, and then the secondary bidirectional threaded rod 12 drives the positioning seat body 14 of the outer walls on the front and rear sides to slide, so as to adapt to the installation and positioning of steel structures of different specifications.

Embodiment 2: In order to solve the problem that the existing steel structure is prone to deviation during the positioning process, this embodiment adopts the following technical solutions: the top surfaces of the symmetrically arranged positioning seats 14 are slidably provided with pressure slide plates 15, and the bottom surfaces of the pressure slide plates 15 and the positioning seats 14 are connected to each other through the resistance springs 16; the outer sides of the symmetrically arranged positioning seats 14 are rotatably connected to the outer ends of the pressure resistance plates 17 through bearings, and the pressure resistance plates 17 and the positioning seats 14 are connected to each other through the return springs 18, and the pressure resistance plates 17 and the pressure slide plates 15 are connected to each other through the traction ropes 19;

As shown in Figures 6 and 7, when the steel structure needs to be limited, the steel structure is placed above the pressure slide 15 on the top surface of the positioning seat 14, and its weight drives the pressure slide 15 to slide downward, and then the pressure slide 15 drives the traction rope 19 to tighten, and then the tightened traction rope 19 drives the pressure resistance plate 17 fixedly connected to its top to flip downward, so that the pressure resistance plate 17 can cover the top of the steel structure, thereby preventing the steel structure from shifting.

Embodiment 3: In order to solve the problem of unstable docking of existing steel structures during welding, this embodiment adopts the following technical scheme, wherein the main bidirectional threaded rod 6 connected by the sprocket mechanism 8 inside the rotation driving cavity 3 is rotated, so that the main bidirectional threaded rod 6 drives the guide sliders 9 connected by threads on the left and right sides and the positioning brackets 7 on the top surface to move, and the positioning seats 14 on the front and rear sides of the positioning brackets 7 drive the steel structure to slide inward synchronously, so as to perform welding work through the welding gun head 20;

A driving cavity 3 is provided inside the bearing base 1, and a driving mechanism is provided in the driving cavity 3 inside the bearing base 1; wherein the driving mechanism comprises a main bidirectional threaded rod 6, and the main bidirectional threaded rod 6 is symmetrically installed on the front and rear sides of the driving cavity 3 through bearings; the right end of the main bidirectional threaded rod 6 included in the driving mechanism is meshed and connected through a sprocket mechanism 8, and the left and right outer walls of the main bidirectional threaded rod 6 on the front and rear sides are both threadedly connected to the outer ends of the guide sliders 9, and the top ends of the guide sliders 9 on the left and right sides are fixedly connected to the bottom ends of the positioning brackets 7 included in the positioning mechanism;

A protective top plate 4 is arranged above the bearing base 1, and a welding gun head 20 is fixedly arranged at the center position of the bottom surface of the protective top plate 4; support side plates 2 are fixedly installed on the left and right sides of the bearing base 1; the top ends of the symmetrically arranged support side plates 2 are fixedly connected to the outer ends of the bottom surface of the protective top plate 4, and a feed slot 5 is opened below the symmetrically arranged support side plates 2, and the symmetrically arranged support side plates 2 facilitate positioning and welding of steel structures of different specifications through the feed slot 5 opened below;

As shown in Figures 1 to 3, the steel structure after positioning and locking is located above the positioning bracket 7. Then when welding is required, the main bidirectional threaded rod 6 engaged by the sprocket mechanism 8 is manually rotated to drive the guide slider 9 threadedly connected to the outer wall to move inside the driving cavity 3, and the guide slider 9 drives the upper positioning bracket 7 and the steel structure locked by the positioning seat body 14 to move in opposite directions, so as to drive the end of the steel structure to be brought closer, and the welding work is performed through the welding gun head 20 on the bottom surface of the protective top plate 4, so as to ensure the accuracy of the steel structure welding.

Although the present invention has been described in detail with reference to the aforementioned embodiments, those skilled in the art may still modify the technical solutions described in the aforementioned embodiments, or make equivalent substitutions for some of the technical features therein. Any modifications, equivalent substitutions, improvements, etc. made within the spirit and principles of the present invention shall be included in the protection scope of the present invention.

Claims (7)

1. The welding device for processing the steel structure comprises a bearing base (1) and supporting side plates (2) fixedly arranged on the left side and the right side of the bearing base (1);

A driving cavity (3) is formed in the bearing base (1), and a driving mechanism is arranged in the driving cavity (3) in the bearing base (1);

characterized by further comprising:

A protective top plate (4) is arranged above the bearing base (1), and a welding gun head (20) is fixedly arranged at the center of the bottom surface of the protective top plate (4);

The driving mechanism comprises a main bidirectional threaded rod (6), and the main bidirectional threaded rod (6) is symmetrically arranged at the front side and the rear side of the inside of the driving cavity (3) through bearings;

Wherein, the top of carrying base (1) inside drive cavity (3) is provided with positioning mechanism, and positioning mechanism includes locating support (7), and locating support (7) symmetry slip set up in the top left and right sides that carries base (1).

2. The welding device for machining steel structures according to claim 1, wherein: the top of support curb plate (2) that the symmetry set up is all fixed connection in protection roof (4) bottom surface outer end, and feed slot (5) have been seted up to the below of support curb plate (2) that the symmetry set up to the steel construction that support curb plate (2) that the symmetry set up through feed slot (5) that the below was seted up is convenient for different specifications is fixed a position and the welding work.

3. The welding device for machining steel structures according to claim 1, wherein: the right end of the main bidirectional threaded rod (6) contained in the driving mechanism is connected in a meshed mode through a chain wheel mechanism (8), the outer walls of the left side and the right side of the main bidirectional threaded rod (6) on the front side and the rear side are connected with the outer ends of the guide sliding blocks (9) in a threaded mode, and the top ends of the guide sliding blocks (9) on the left side and the right side are fixedly connected with the bottom ends of the positioning supports (7) contained in the positioning mechanism.

4. The welding device for machining steel structures according to claim 1, wherein: the bearing base is characterized in that the front side and the rear side of the top surface of the bearing base (1) are respectively provided with the outer ends of guide rotating shafts (10) through bearings in a rotating mode, the outer walls of the left side and the right side of the guide rotating shafts (10) on the front side and the rear side are respectively provided with a main bevel gear (11) in a sliding mode, and the guide rotating shafts (10) which are symmetrically arranged are connected with the main bevel gears (11) in a clamping mode through protrusions of the outer walls.

5. The welding device for machining steel structures according to claim 1, wherein: the positioning mechanism comprises an auxiliary bidirectional threaded rod (12), the auxiliary bidirectional threaded rod (12) is rotatably arranged in the positioning support (7) through a bearing, auxiliary bevel gears (13) are fixedly arranged at the front end and the rear end of the auxiliary bidirectional threaded rod (12) at the left side and the right side, and the auxiliary bevel gears (13) are in meshed connection with the main bevel gears (11) which are correspondingly distributed.

6. The welding device for steel structure processing according to claim 5, wherein: the positioning mechanism comprises a positioning seat body (14), the bottom end of the positioning seat body (14) is in threaded connection with the outer walls of the front side and the rear side of the auxiliary bidirectional threaded rod (12), the top surfaces of the symmetrically arranged positioning seat bodies (14) are respectively provided with a pressure sliding plate (15) in a sliding mode, and the bottom surfaces of the pressure sliding plates (15) are connected with the positioning seat body (14) through abutting springs (16).

7. The welding device for machining steel structures according to claim 6, wherein: the outside of symmetry setting location pedestal (14) all rotates through the bearing and connects in the outer end of pressure conflict board (17), and connects each other through reset spring (18) between pressure conflict board (17) and location pedestal (14) to connect each other through traction rope (19) between pressure conflict board (17) and the pressure slide (15).