CN215509686U - Automatic welding equipment for box-type steel plate shear wall - Google Patents

Abstract

The utility model belongs to the technical field of shear walls, and particularly relates to automatic welding equipment for a box-type steel plate shear wall, which comprises a transverse H-shaped steel plate and a vertical H-shaped steel plate; the two side wall surfaces of the vertical H-shaped steel plate are fixedly connected with sliding rail mechanisms; the upper end of the vertical H-shaped steel plate is connected with an equipment platform in a buckling mode; the sliding blocks are connected inside the sliding rail mechanisms in a sliding mode; the upper side and the lower side of the tail end of the sliding block are fixedly connected with supporting rods with equal length; the top of the supporting rod is fixedly connected with a first connecting beam; the utilization can be fixed mounting in the slide rail mechanism on erecting the H steel sheet, drives its inside slider horizontal migration in slide rail mechanism's inside to under hydraulic cylinder's drive, make the slider front end can be inseparable support by on the lateral wall of horizontal H steel sheet, thereby can will erect H steel sheet vertically and fix on horizontal H steel sheet, realize avoiding steel sheet shear force wall horizontal load and vertical load to receive the influence to erecting H steel sheet and the perpendicular determination of relation of connection of horizontal H steel sheet.

Description

Automatic welding equipment for box-type steel plate shear wall

Technical Field

The utility model belongs to the technical field of shear walls, and particularly relates to automatic welding equipment for a box-type steel plate shear wall.

Background

Shear walls are also known as wind resistant walls, seismic walls or structural walls. The wall body mainly bears horizontal load and vertical load caused by wind load or earthquake action in a house or a structure to prevent the shearing damage of the structure, and is also called as an anti-seismic wall and is generally made of reinforced concrete.

At present, in the prior art, when a steel plate type shear wall is welded, the deviation of an angle generated after the final welding of a horizontal H steel plate and a vertical H steel plate is not easy to determine due to the position relation between the horizontal H steel plate and the vertical H steel plate, so that the horizontal load and the vertical load of the box-type steel plate shear wall are greatly influenced.

SUMMERY OF THE UTILITY MODEL

In order to make up the defects of the prior art, the automatic welding equipment for the box-type steel plate shear wall is provided.

The technical scheme adopted by the utility model for solving the technical problems is as follows: the automatic welding equipment for the box-type steel plate shear wall comprises a transverse H-shaped steel plate and a vertical H-shaped steel plate; the two side wall surfaces of the vertical H-shaped steel plate are fixedly connected with sliding rail mechanisms; the upper end of the vertical H-shaped steel plate is connected with an equipment platform in a buckling mode; the sliding blocks are connected inside the sliding rail mechanisms in a sliding mode; the upper side and the lower side of the tail end of the sliding block are fixedly connected with supporting rods with equal length; the top of the supporting rod is fixedly connected with a first connecting beam;

preferably, the upper end of the equipment platform is fixedly connected with a hydraulic oil cylinder; the other end of the hydraulic oil cylinder is fixedly connected to the side wall of the first connecting beam.

Preferably, symmetrical mounting holes are formed in the side wall of the upper end of the vertical H-shaped steel plate in a penetrating mode; the middle part of the vertical H-shaped steel plate is separated into a plurality of cavities.

Preferably, the inner side wall of the slide rail mechanism is provided with a bolt hole; the upper wall surface and the lower wall surface of the slide rail mechanism are provided with first sliding chutes; a second sliding groove is formed in the outer side wall of the sliding rail mechanism; the inside sliding connection of slide rail mechanism has the slider.

Preferably, the front end of the sliding block is fixedly connected with a fit rod; and a spring is fixedly connected to the side wall of the tail end of the sliding block.

Preferably, the support rod is connected in the first sliding groove in a sliding manner; the other end of the spring is fixedly connected to the inner bottom surface of the sliding rail mechanism.

Preferably, the lower end of the equipment platform is fixedly connected with a plurality of partition plates at intervals; the partition plate is connected to the inner side wall of the vertical H-shaped steel plate in a fit manner; a groove is formed in the surface of the equipment platform; the hydraulic oil cylinder is fixed in the groove.

Preferably, both ends of the first connecting beam are provided with first through holes which penetrate through the first connecting beam; the middle part of the front side of the first connecting beam is provided with a first connecting hole; the other end of the hydraulic oil cylinder is fixedly connected in the first connecting hole.

Preferably, the bolt hole on the slide rail mechanism is coaxially fixed with the mounting hole on the vertical H-shaped steel plate, and the slide rail mechanism is fixedly connected with the vertical H-shaped steel plate through a bolt.

Preferably, the top end of the supporting rod is connected in the first through hole in a through hole; the top of the supporting rod is connected with a limiting part through a hole.

The utility model has the beneficial effects that: the utilization can be fixed mounting in the slide rail mechanism on erecting the H steel sheet, drives its inside slider horizontal migration in slide rail mechanism's inside to under hydraulic cylinder's drive, make the slider front end can be inseparable support by on the lateral wall of horizontal H steel sheet, thereby can will erect H steel sheet vertically and fix on horizontal H steel sheet, realize avoiding steel sheet shear force wall horizontal load and vertical load to receive the influence to erecting H steel sheet and the perpendicular determination of relation of connection of horizontal H steel sheet.

The utility model provides automatic welding equipment for a box-type steel plate shear wall, which is characterized in that the joint of a fixed transverse H-shaped steel plate and a vertical H-shaped steel plate which is fixed by matching a sliding rail mechanism and a sliding block with a vertical angle is welded through external welding equipment, the vertical H-shaped steel plate is fixed at a predetermined position, so that the welding efficiency of the steel plate shear wall is higher, and the occurrence of angle deviation in the welding process can be avoided.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the utility model and together with the description serve to explain the utility model without limiting the utility model. In the drawings:

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a perspective view of the present invention;

FIG. 3 is a perspective view of the slide rail mechanism of the present invention;

FIG. 4 is a perspective view of the slider of the present invention;

FIG. 5 is a perspective view of a first attachment beam of the present invention;

FIG. 6 is a perspective view of a vertical H-shaped steel plate according to the present invention;

FIG. 7 is a perspective view of a second attachment beam of the present invention;

FIG. 8 is a schematic structural view of the second embodiment;

illustration of the drawings:

1. a horizontal H steel plate; 2. erecting an H-shaped steel plate; 21. mounting holes; 22. a cavity; 3. a slide rail mechanism; 31. bolt holes; 32. a first chute; 33. a second chute; 34. a slider; 341. a fit rod; 342. a support bar; 343. a spring; 4. an equipment platform; 41. a partition plate; 42. a groove; 5. a first connecting beam; 51. a first through hole; 52. a first connection hole; 53. a limiting member; 54. a hydraulic cylinder; 6. a second connecting beam; 61. a second through hole; 62. a second connection hole; 63. a connecting rod; 64. a screw rod; 65. a ball nut; 66. an electric motor.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Specific examples are given below.

The first embodiment is as follows:

referring to fig. 1 to 6, the present invention provides an automatic welding device for a box-type steel plate shear wall, which includes a horizontal H-shaped steel plate 1 and a vertical H-shaped steel plate 2; the two side wall surfaces of the vertical H-shaped steel plate 2 are fixedly connected with sliding rail mechanisms 3; the upper end of the vertical H-shaped steel plate 2 is connected with an equipment platform 4 in a buckling mode; the slide rail mechanisms 3 are all connected with slide blocks 34 in a sliding manner; the upper side and the lower side of the tail end of the sliding block 34 are fixedly connected with supporting rods 342 with equal length; the top of the support rod 342 is fixedly connected with a first connecting beam 5.

The upper end of the equipment platform 4 is fixedly connected with a hydraulic oil cylinder 54; the other end of the hydraulic oil cylinder 54 is fixedly connected to the side wall of the first connecting beam 5.

As an embodiment of the present invention, the horizontal H-steel plate 1 is a fixed structure, and the vertical H-steel plate 2 is a structure that moves under the driving of the sliding rail mechanism 3, wherein a hanging hole should be arranged at the upper end of the vertical H-steel plate 2, the vertical H-steel plate 2 is lifted by using an external tower crane device, and the sliding rail mechanism 3 and the sliding block 34 are matched at a proper position to connect the vertical H-steel plate 2 and the horizontal H-steel plate 1, at this time, there is no fixed connection relationship between the vertical H-steel plate 2 and the horizontal H-steel plate 1, which is only a butting relationship, and the movement of the sliding block 34 inside the sliding rail mechanism 3 is driven by the hydraulic cylinder 54 fixed above the vertical H-steel plate 2, so that the sliding block can be butted against the side wall of the horizontal H-steel plate 1, and the fit rod 341 on the front side surface of the sliding block 34 is fittingly connected with the fit groove on the horizontal H-steel plate 1.

Symmetrical mounting holes 21 are formed in the side wall of the upper end of the vertical H-shaped steel plate 2 in a penetrating mode; the middle part of the vertical H-shaped steel plate 2 is divided into a plurality of cavities 22.

According to one embodiment of the utility model, the mounting holes 21 formed in the vertical H-shaped steel plate 2 are used for fixing the sliding rail mechanism 3 before reinforcement, and after the welding process is finished, reinforcing steel bars can be connected into the mounting holes 21 formed in the vertical H-shaped steel plate 2 through holes, so that a reinforcing effect is provided for the box-shaped steel plate shear wall.

The inner side wall of the slide rail mechanism 3 is provided with a bolt hole 31; the upper wall surface and the lower wall surface of the slide rail mechanism 3 are provided with first sliding chutes 32; a second sliding groove 33 is formed in the outer side wall of the sliding rail mechanism 3; a sliding block 34 is connected inside the sliding rail mechanism 3 in a sliding manner.

In an embodiment of the present invention, the bolt hole 31 provided on the inner side wall of the slide rail mechanism 3 and the mounting hole 21 provided on the vertical H-shaped steel plate 2 are coaxially arranged, the slide rail mechanism 3 and the vertical H-shaped steel plate 2 are connected to each other through a bolt hole to realize a fixed connection between the bolt hole 31 and the mounting hole 21, the slider 34 has an "L" shaped structure, one side plate surface thereof is slidably connected to the inside of the slide rail mechanism 3, the other side plate surface thereof is slidably connected to the outer side wall of the slide rail mechanism 3, and the bottom of the other side plate surface can be tightly abutted against the side wall of the horizontal H-shaped steel plate 1.

The front end of the slide block 34 is fixedly connected with a fit rod 341; a spring 343 is fixedly connected to the end side wall of the slider 34.

In an embodiment of the present invention, when the slider 34 moves along with the hydraulic cylinder 54, the plate surface on one side of the slider will eventually contact and adhere to the sidewall of the horizontal H-shaped steel plate 1, and the bottom of the plate surface on one side of the slider 34 is fixedly connected with the engaging rod 341, so that when the slider 34 moves onto the horizontal H-shaped steel plate 1, the slider 34 will engage and connect with the inside of the horizontal H-shaped steel plate 1, thereby making the connection between the slider 34 and the sidewall of the horizontal H-shaped steel plate 1 more tight, and the vertical H-shaped steel plate 2 can be vertically connected to the horizontal H-shaped steel plate 1 by the engagement between the sliders 34 on both sides.

The supporting rod 342 is slidably connected in the first sliding groove 32; the other end of the spring 343 is fixedly connected to the inner bottom surface of the slide rail mechanism 3.

The lower end of the equipment platform 4 is fixedly connected with a plurality of partition plates 41 at intervals; the partition plate 41 is connected to the inner side wall of the vertical H-shaped steel plate 2 in a fit manner; a groove 42 is formed on the surface of the equipment platform 4; the hydraulic ram 54 is secured within the recess 42.

As an embodiment of the present invention, the bottom of the equipment platform 4 is provided with four partition plates 41, two adjacent partition plates 41 are combined to form a limit buckle structure, and the gap between two adjacent partition plates 41 is similar to the size of the middle partition of the vertical H steel plate 2, so that the equipment platform 4 can be buckled and connected above the vertical H steel plate 2 by means of the partition plates 41, and the hydraulic cylinder 54 is fixedly connected in the groove 42 on the upper side of the equipment platform 4, and the other end of the hydraulic cylinder is fixedly connected in the middle first connection hole 52 of the first connection beam 5.

Both ends of the first connecting beam 5 are provided with first through holes 51 which penetrate through the first connecting beam; a first connecting hole 52 is formed in the middle of the front side of the first connecting beam 5; the other end of the hydraulic cylinder 54 is fixedly connected in the first connecting hole 52.

The bolt hole 31 on the slide rail mechanism 3 is coaxially fixed with the mounting hole 21 on the vertical H-shaped steel plate 2, and the slide rail mechanism 3 is fixedly connected with the vertical H-shaped steel plate 2 through bolts.

The top end of the supporting rod 342 is connected in the first through hole 51 in a penetrating way; the top of the supporting rod 342 is connected with a limiting member 53 through a hole.

As an embodiment of the present invention, the supporting rods 342 fixedly connected to the upper and lower sides of the end of the sliding block 34 are fixedly connected to the first through holes 51 inside the first connecting beam 5, and the upper ends of the supporting rods are provided with the limiting members 53, that is, the first connecting beam 5 is limited on the upper sides of the supporting rods 342 at the two ends by the limiting members 53, so that the sliding block 34 inside the slide rail mechanism 3 can be indirectly driven to slide by the hydraulic oil cylinder 54.

Example two:

referring to fig. 7-8, in the first embodiment, the movement of the sliding block 34 needs to be driven by the hydraulic cylinder 54 on the equipment platform 4, and the first connecting beam 5 connected to the supporting rods 342 at the two ends is matched to drive the sliding blocks 34 at the two ends to slide towards the front end at equal intervals inside the sliding rail mechanism 3, so as to finally achieve the effect of vertically fixing the vertical H-shaped steel plate 2 on the horizontal H-shaped steel plate 1, and the hydraulic cylinder 54 can be replaced by a structure comprising a connecting rod 63, a screw rod 64, a ball nut 65 and a motor 66, wherein the motor 66 is a replacement power source of the hydraulic cylinder 54, the screw rod 64 is fixedly connected to the transmission end of the motor 66, and the ball nut 65 is screwed on the screw rod 64; the connecting rod 63 is fixedly connected to the back side of the ball nut 65, when the operation is performed, an operator starts the motor 66 to drive the screw rod 64 to rotate, so that the screw rod 64 and the ball nut 65 rotate relatively, the position of the screw rod 64 does not change due to the rotation of the screw rod 64 at the transmission end of the motor 66, so that the ball nut 65 drives the connecting rod 63 to displace relative to the screw rod 64, and the effect of finally driving the slider 34 to move is realized, wherein the first connecting beam 5 in the first embodiment can be replaced by a second connecting beam 6, because the number of the connecting rods 63 is two, the connecting rod 342 is connected by a second connecting beam 6 with a specific structure, wherein the second connecting beam 6 is also provided with symmetrical second through holes 61, the front side wall surface of the second connecting beam 6 is provided with symmetrical second connecting holes 62, and the other end of the connecting rod 63 is fixedly connected in the second connecting holes 62, the second connecting beam 6 is fixedly connected, and the second connecting beam 6 is driven to move through the relative rotation between the screw rod 64 and the ball nut 65, so that the sliding block 34 at the bottom is indirectly driven to slide.

The working principle is as follows: the first embodiment is as follows: referring to fig. 1-6, the transverse H-shaped steel plate 1 is a fixed structure, the vertical H-shaped steel plate 2 is a structure that moves under the driving of the sliding rail mechanism 3, wherein a hanging hole should be arranged at the upper end of the vertical H-shaped steel plate 2, the vertical H-shaped steel plate 2 is hung by using an external tower crane device and is connected with the transverse H-shaped steel plate 1 by matching the sliding rail mechanism 3 with the sliding block 34 at a proper position, at this time, there is no fixed connection relationship between the vertical H-shaped steel plate 2 and the transverse H-shaped steel plate 1, which is only a butting relationship, and the sliding block 34 moves inside the sliding rail mechanism 3 by being driven by the hydraulic cylinder 54 fixed above the vertical H-shaped steel plate 2, so that the sliding block can be butted with the side wall of the transverse H-shaped steel plate 1, and the mating rod 341 on the front side surface of the sliding block 34 is mated with the mating groove on the transverse H-shaped steel plate 1, the mounting hole 21 arranged on the vertical H-shaped steel plate 2 is used for fixing the sliding rail mechanism 3 before being reinforced, after the welding process is finished, reinforcing steel bars can be connected in the mounting holes 21 on the vertical H-shaped steel plates 2 in a perforation mode to provide a reinforcing effect for the box-shaped steel plate shear wall, the bolt holes 31 formed in the inner side walls of the slide rail mechanisms 3 and the mounting holes 21 formed in the vertical H-shaped steel plates 2 are coaxially arranged, the slide rail mechanisms 3 and the vertical H-shaped steel plates 2 are fixedly connected in the bolt holes 31 and the mounting holes 21 through bolt perforation connection, the slide block 34 is of an L-shaped structure, one side plate surface of the slide block is connected in the slide rail mechanisms 3 in a sliding mode, the other side plate surface of the slide block slides on the outer side wall of the slide rail mechanisms 3, the bottom of the other side plate surface can be tightly abutted against the side wall of the transverse H-shaped steel plate 1, when the slide block 34 moves along with the hydraulic oil cylinder 54, the plate surface on one side of the slide block is finally in contact with the side wall of the transverse H-shaped steel plate 1, and the bottom of the plate surface on one side of the slide block 34 is fixedly connected with the conjunction rod 341, when the sliding block 34 moves to the transverse H-shaped steel plate 1, the sliding block 34 is connected in the transverse H-shaped steel plate 1 in a fit manner, so that the sliding block 34 is more tightly connected with the side wall of the transverse H-shaped steel plate 1, the vertical H-shaped steel plate 2 can be vertically connected to the transverse H-shaped steel plate 1 through the matching between the sliding blocks 34 on the two sides, the bottom of the equipment platform 4 is provided with four partition plates 41, two adjacent partition plates 41 are combined to form a limiting buckle structure, the gap between the two adjacent partition plates 41 is similar to the size of the middle partition of the vertical H-shaped steel plate 2, so that the equipment platform 4 can be connected above the vertical H-shaped steel plate 2 through the buckle of the partition plates 41, the hydraulic oil cylinder 54 is fixedly connected in the groove 42 on the upper side of the equipment platform 4, the other end of the hydraulic oil cylinder is fixedly connected in the first connecting hole 52 in the middle of the first connecting beam 5, and the supporting rods 342 fixedly connected on the upper side and the lower side of the tail end of the sliding block 34, the first connecting beam 5 is fixedly connected to the first through hole 51 inside the first connecting beam 5, and the upper end of the first connecting beam is provided with a limiting member 53, that is, the first connecting beam 5 is limited on the upper sides of the supporting rods 342 at the two ends by the limiting member 53, so that the sliding block 34 inside the slide rail mechanism 3 can be indirectly driven to slide under the driving of the hydraulic oil cylinder 54.

Example two: referring to fig. 7-8, in the first embodiment, the movement of the sliding blocks 34 needs to be driven by the hydraulic cylinders 54 on the equipment platform 4, and the first connecting beams 5 connected to the supporting rods 342 at the two ends are matched to drive the sliding blocks 34 at the two ends to slide towards the front ends at equal intervals inside the sliding rail mechanism 3, so as to finally achieve the effect of vertically fixing the vertical H-shaped steel plate 2 on the horizontal H-shaped steel plate 1, and the hydraulic cylinders 54 can be replaced by the following structure comprising the connecting rods 63, the lead screws 64, the ball nuts 65 and the motors 66, wherein the motors 66 are the replacing power sources of the hydraulic cylinders 54, the lead screws 64 are fixedly connected to the transmission ends of the motors 66, and the ball nuts 65 are screwed on the lead screws 64; the connecting rod 63 is fixedly connected to the back side of the ball nut 65, when the operation is performed, an operator starts the motor 66 to drive the screw rod 64 to rotate, so that the screw rod 64 and the ball nut 65 rotate relatively, the position of the screw rod 64 does not change due to the rotation of the screw rod 64 at the transmission end of the motor 66, so that the ball nut 65 drives the connecting rod 63 to displace relative to the screw rod 64, and the effect of finally driving the slider 34 to move is realized, wherein the first connecting beam 5 in the first embodiment can be replaced by a second connecting beam 6, because the number of the connecting rods 63 is two, the connecting rod 342 is connected by a second connecting beam 6 with a specific structure, wherein the second connecting beam 6 is also provided with symmetrical second through holes 61, the front side wall surface of the second connecting beam 6 is provided with symmetrical second connecting holes 62, and the other end of the connecting rod 63 is fixedly connected in the second connecting holes 62, the second connecting beam 6 is fixedly connected, and the second connecting beam 6 is driven to move through the relative rotation between the screw rod 64 and the ball nut 65, so that the sliding block 34 at the bottom is indirectly driven to slide.

In the description herein, references to the description of "one embodiment," "an example," "a specific example" or the like are intended to mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the utility model. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The foregoing shows and describes the general principles, essential features, and advantages of the utility model. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the utility model as claimed.

Claims (10)

1. The utility model provides a box steel sheet shear force wall automated welding equipment which characterized in that: comprises a horizontal H steel plate (1) and a vertical H steel plate (2); the two side wall surfaces of the vertical H-shaped steel plate (2) are fixedly connected with sliding rail mechanisms (3); the upper end of the vertical H-shaped steel plate (2) is connected with an equipment platform (4) in a buckling mode; the slide rail mechanisms (3) are internally and respectively connected with a slide block (34) in a sliding way; the upper side and the lower side of the tail end of the sliding block (34) are fixedly connected with supporting rods (342) with equal length; the top of the supporting rod (342) is fixedly connected with a first connecting beam (5).

2. The automatic welding equipment for the box-type steel plate shear wall according to claim 1, wherein the welding equipment comprises: the upper end of the equipment platform (4) is fixedly connected with a hydraulic oil cylinder (54); the other end of the hydraulic oil cylinder (54) is fixedly connected to the side wall of the first connecting beam (5).

3. The automatic welding equipment for the box-type steel plate shear wall according to claim 1, wherein the welding equipment comprises: symmetrical mounting holes (21) are formed in the side wall of the upper end of the vertical H-shaped steel plate (2) in a penetrating mode; the middle part of the vertical H-shaped steel plate (2) is separated into a plurality of cavities (22).

4. The automatic welding equipment for the box-type steel plate shear wall according to claim 1, wherein the welding equipment comprises: a bolt hole (31) is formed in the inner side wall of the slide rail mechanism (3); the upper wall surface and the lower wall surface of the slide rail mechanism (3) are provided with first sliding chutes (32); a second sliding chute (33) is formed in the outer side wall of the sliding rail mechanism (3); the slide rail mechanism (3) is internally and slidably connected with a slide block (34).

5. The automatic welding equipment for the box-type steel plate shear wall according to claim 1, wherein the welding equipment comprises: the front end of the sliding block (34) is fixedly connected with a conjunction rod (341); and a spring (343) is fixedly connected to the side wall of the tail end of the sliding block (34).

6. The automatic welding equipment for the box-type steel plate shear wall of claim 5, wherein the welding equipment comprises: the supporting rod (342) is connected in the first sliding groove (32) in a sliding way; the other end of the spring (343) is fixedly connected to the bottom surface of the inner side of the sliding rail mechanism (3).

7. The automatic welding equipment for the box-type steel plate shear wall according to claim 2, characterized in that: the lower end of the equipment platform (4) is fixedly connected with a plurality of partition plates (41) at intervals; the partition plate (41) is connected to the inner side wall of the vertical H-shaped steel plate (2) in a fit manner; a groove (42) is formed in the surface of the equipment platform (4); the hydraulic oil cylinder (54) is fixed in the groove (42).

8. The automatic welding equipment for the box-type steel plate shear wall according to claim 2, characterized in that: both ends of the first connecting beam (5) are provided with first through holes (51) which penetrate through; the middle part of the front side of the first connecting beam (5) is provided with a first connecting hole (52); the other end of the hydraulic oil cylinder (54) is fixedly connected in the first connecting hole (52).

9. The automatic welding equipment for the box-type steel plate shear wall according to claim 1, wherein the welding equipment comprises: bolt holes (31) in the sliding rail mechanism (3) are coaxially fixed with mounting holes (21) in the vertical H-shaped steel plate (2), and the sliding rail mechanism (3) is fixedly connected with the vertical H-shaped steel plate (2) through bolts.

10. The automatic welding equipment for the box-type steel plate shear wall according to claim 1, wherein the welding equipment comprises: the top end of the supporting rod (342) is connected in the first through hole (51) in a penetrating way; the top of the supporting rod (342) is connected with a limiting piece (53) through a hole.

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