CN218425347U - Steel reinforcement cage welding set - Google Patents

Abstract

The utility model provides a steel reinforcement cage welding set, includes the frame, is equipped with longitudinal rail, shaping mandrel and longitudinal reinforcement locating part in the frame, and longitudinal reinforcement locating part locates around the shaping mandrel, is equipped with bending forming mechanism, welding mechanism and vertical feed mechanism on the longitudinal rail. The welding method comprises the steps of S1, positioning a reinforcement cage; s2, primary welding of transverse steel bars: the welding mechanism welds the crossed part of the transverse steel bar and the longitudinal steel bar; s3, primary bending of the transverse steel bars: the welding mechanism moves a set distance along the longitudinal guide rail to be separated from the transverse steel bars, and the bending forming mechanism moves to the position of the transverse steel bars and preliminarily bends the transverse steel bars; s4, welding the transverse steel bars again; s5, bending the transverse steel bars again; s6, bending the transverse steel bars into annular stirrups, and executing a step S7; otherwise, repeating the steps S4 to S5 until the transverse steel bar is bent into a hoop reinforcement; and S7, repeating the steps S1 to S6 until the reinforcement cage is welded. The utility model discloses simple structure, compactness, degree of automation is high, is favorable to improving production efficiency.

Description

Steel reinforcement cage welding set

Technical Field

The utility model relates to a reinforcing bar processing equipment and processing method thereof especially relate to a steel reinforcement cage welding set.

Background

The existing automatic production equipment for steel bar trusses (or called steel bar cages) is mainly applied to the automatic production of precast concrete members, such as laminated slab triangular trusses. The lower opening of the triangular truss is of an opening structure, so that automatic continuous production is easy to realize. However, for a truss beam and a dust removal mesh bag framework with a closed hoop reinforcement, the hoop reinforcement is generally bent and formed by a reinforcement forming device independently, then is manually sleeved on a welding position on a longitudinal reinforcement, and finally is automatically welded by a welding device. Such semi-automatic production mode efficiency is lower, and workman's intensity of labour is also great simultaneously.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to overcome the not enough of prior art, provide a simple structure, compactness, degree of automation is high, is favorable to improving production efficiency's steel reinforcement cage welding set.

The utility model further provides an above-mentioned steel reinforcement cage welding set's welding method.

In order to solve the technical problem, the utility model discloses a following technical scheme:

the utility model provides a steel reinforcement cage welding set, includes the frame, be equipped with longitudinal rail, shaping mandrel and longitudinal reinforcement locating part in the frame, longitudinal reinforcement locating part locates around the shaping mandrel, be equipped with bending forming mechanism, welding mechanism and be used for driving the longitudinal feed mechanism of steel reinforcement cage along longitudinal movement on the longitudinal rail.

As a further improvement of the technical scheme: the side of the welding mechanism is also provided with a transverse steel bar feeding mechanism and a transverse steel bar shearing mechanism.

As a further improvement of the above technical solution: the machine frame is also provided with a longitudinal steel bar shearing mechanism, and the longitudinal steel bar shearing mechanism and the forming core mold are respectively arranged at two ends of the machine frame.

As a further improvement of the technical scheme: the machine frame is provided with a lifting mechanism, and the longitudinal steel bar shearing mechanism is arranged on the lifting mechanism.

As a further improvement of the above technical solution: the bending forming mechanism is connected with the welding mechanism to synchronously move along the longitudinal guide rail.

As a further improvement of the technical scheme: the bending forming mechanism comprises a first mounting seat arranged on the longitudinal guide rail, and a lifting driving part and a transverse moving driving part which are arranged on the first mounting seat, wherein first forming parts used for bending transverse reinforcing steel bars are arranged on the left side and the right side below the forming core die, second forming parts are arranged on the left side and the right side above the forming core die, the lifting driving part is connected with the first forming parts, and the transverse moving driving part is connected with the second forming parts.

As a further improvement of the above technical solution: the lifting driving part is of a telescopic structure and is arranged below the forming core mould, the transverse moving driving part is of a telescopic structure and is provided with two parts, the two transverse moving driving parts are oppositely arranged at the left side and the right side of the forming core mould, and the second forming part positioned at the same side of the forming core mould is connected with the transverse moving driving part.

As a further improvement of the above technical solution: the longitudinal steel bar positioning part is a positioning sleeve.

As a further improvement of the technical scheme: the longitudinal feeding mechanism comprises a second mounting seat arranged on the longitudinal guide rail and a reinforcement cage clamping mechanism arranged on the second mounting seat.

The welding method of the reinforcement cage welding device comprises the following steps:

s1, positioning a reinforcement cage: the longitudinal feeding mechanism drives the reinforcement cage to move for a set distance along the longitudinal guide rail;

s2, primary welding of transverse steel bars: the welding mechanism welds and fixes the crossed part of the transverse steel bar and the longitudinal steel bar;

s3, primary bending of the transverse steel bars: the welding mechanism moves a set distance along the longitudinal guide rail to be separated from the transverse steel bars, and the bending forming mechanism moves to the position of the transverse steel bars and preliminarily bends the transverse steel bars;

s4, welding the transverse steel bars again: the bending forming mechanism moves to an initial position to be separated from the transverse steel bars, and the welding mechanism moves to the initial position to weld and fix the crossed parts of the bent parts of the transverse steel bars and the longitudinal steel bars;

s5, bending the transverse steel bars again: the welding mechanism moves a set distance along the longitudinal guide rail to be separated from the transverse steel bars, and the bending forming mechanism moves to the position of the transverse steel bars and bends the transverse steel bars again;

s6, if the transverse steel bars are already bent into the hoop reinforcements, executing the step S7; if the transverse steel bars are not bent into the hoop reinforcement, repeating the steps S4 to S5 until the transverse steel bars are bent into the hoop reinforcement;

s7, repeating the steps from S1 to S6 until the reinforcement cage is welded;

or, comprising the steps of:

s1, positioning a reinforcement cage: the longitudinal feeding mechanism drives the reinforcement cage to move for a set distance along the longitudinal guide rail;

s2, primarily bending the transverse steel bars: the bending forming mechanism is used for preliminarily bending the transverse steel bar;

s3, primary welding of transverse steel bars: the bending forming mechanism moves for a set distance along the longitudinal guide rail to be separated from the transverse steel bars, and the welding mechanism moves to the position of the transverse steel bars along the longitudinal guide rail and welds and fixes the crossed parts of the transverse steel bars and the longitudinal steel bars;

s4, bending the transverse steel bars again: the welding mechanism moves to an initial position to be separated from the transverse steel bar, and the bending forming mechanism moves to the initial position and bends the transverse steel bar again;

s5, welding the transverse steel bars again: the bending forming mechanism moves a set distance along the longitudinal guide rail to be separated from the transverse steel bars, moves to the position of the transverse steel bars again and welds and fixes the bent parts of the transverse steel bars and the crossed parts of the longitudinal steel bars;

s6, if the transverse steel bars are already bent into the hoop reinforcements, executing the step S7; if the transverse steel bars are not bent into the hoop reinforcements, repeating the steps S4 to S5 until the transverse steel bars are bent into the hoop reinforcements;

and S7, repeating the steps S1 to S6 until the reinforcement cage is welded.

Compared with the prior art, the utility model has the advantages of: the utility model discloses a steel reinforcement cage welding set, during the use, at first arrange each longitudinal reinforcement respectively on longitudinal reinforcement locating part, make longitudinal reinforcement encircle around the shaping mandrel, arrange the transverse reinforcement on welding mechanism, drive steel reinforcement cage longitudinal movement by vertical feed mechanism, by welding mechanism, bending mechanism accomplishes transverse reinforcement and longitudinal reinforcement cross position's welding and the shaping of bending of transverse reinforcement in turn, can be fixed with the shape of reinforcing bar shaping part, set for the shape with the shaping mandrel and keep unanimous, can not influence the last shaping shape during next shaping, and then guarantee the shaping quality of hoop reinforcement. The utility model has the advantages of simple and compact overall structure, go out hoop reinforcement while the shaping with hoop reinforcement welded fastening on longitudinal reinforcement, need not manual placing, degree of automation is high, production efficiency is high.

The utility model discloses a welding method of steel reinforcement cage welding set, drive steel reinforcement cage longitudinal movement by vertical feed mechanism, by welding mechanism, bend forming mechanism accomplishes the welding of horizontal reinforcing bar and each cross position of longitudinal reinforcement and the bending shaping of horizontal reinforcing bar in turn along longitudinal rail's reciprocating motion, can be fixed with the shape of reinforcing bar shaping part, set for the shape with the shaping mandrel and keep unanimous, can not influence the last one shot forming shape when the next time forming, and then guarantee the shaping quality of hoop stirrup, go out the hoop stirrup welded fastening on longitudinal reinforcement when the shaping, need not manual the placing, degree of automation is high, high production efficiency.

Drawings

Fig. 1 is the three-dimensional structure schematic diagram of the steel reinforcement cage welding device of the utility model.

Fig. 2 is the structure schematic diagram is looked after the utility model discloses steel reinforcement cage welding set simplifies.

Fig. 3 is the overlooking structure schematic diagram after the reinforcement cage welding device of the utility model is simplified.

Fig. 4 is the utility model discloses side-looking structural schematic diagram after steel reinforcement cage welding set simplifies.

Fig. 5 is a schematic perspective view of a bending forming mechanism of the present invention.

Fig. 6 is a schematic perspective view of a first view angle of the forming core mold according to the present invention.

Fig. 7 is a schematic perspective view of the forming core mold according to the present invention at a second viewing angle.

Fig. 8 is a process schematic diagram of the welding method of the reinforcement cage of the present invention.

Fig. 9 is a three-dimensional structure schematic diagram of the reinforcement cage obtained by welding of the utility model.

The reference numerals in the figures denote: 1. a frame; 11. a longitudinal guide rail; 12. forming a core mold; 13. a longitudinal reinforcement positioning member; 21. a transverse reinforcement bar feeding mechanism; 22. a transverse steel bar shearing mechanism; 31. a longitudinal steel bar shearing mechanism; 32. a lifting mechanism; 4. a bending forming mechanism; 41. a lifting drive member; 42. a traverse driving member; 43. a first molding member; 44. a second molding member; 45. a first mounting seat; 5. a welding mechanism; 6. a reinforcement cage; 61. transverse reinforcing steel bars; 62. longitudinal reinforcing steel bars: 63. hoop reinforcement; 7. a longitudinal feed mechanism; 71. a second mounting seat; 72. reinforcing cage fixture.

Detailed Description

As used in this section and in the claims, the terms "a," "an," "the," and/or "the" are not intended to be inclusive in the singular, but may include the plural unless the context clearly dictates otherwise. The use of "first," "second," and the like in this disclosure is not intended to indicate any order, quantity, or importance, but rather is used to distinguish one element from another. Likewise, the word "comprising" or "comprises", and the like, means that the element or item listed before the word covers the element or item listed after the word and its equivalents, but does not exclude other elements or items. The terms "connected" or "coupled" and the like are not restricted to physical or mechanical connections, but may include electrical connections, whether direct or indirect.

The invention is described in further detail below with reference to the drawings and specific examples.

Example one

As shown in fig. 1 to 7, the utility model discloses steel reinforcement cage welding set's an embodiment, steel reinforcement cage welding set of this embodiment, including frame 1, be equipped with longitudinal rail 11 (the vertical length direction who is steel reinforcement cage 6), shaping mandrel 12 and longitudinal reinforcement locating part 13 in the frame 1, longitudinal reinforcement locating part 13 locates shaping mandrel 12 around, is equipped with on the longitudinal rail 11 to bend forming mechanism 4, welding mechanism 5 and is used for driving steel reinforcement cage 6 along longitudinal movement's vertical feed mechanism 7. Preferably, the longitudinal reinforcing bar positioning member 13, the forming core mold 12, the bending forming mechanism 4, the welding mechanism 5, and the longitudinal feeding mechanism 7 may be arranged in order in the longitudinal direction.

When the reinforcement cage welding device of the embodiment is used, firstly, each longitudinal reinforcement 62 is respectively arranged on the longitudinal reinforcement positioning part 13, so that the longitudinal reinforcement 62 is wound around the forming core mould 12, the transverse reinforcement 61 is arranged on the welding mechanism 5, the longitudinal feeding mechanism 7 drives the reinforcement cage 6 to move longitudinally, the welding mechanism 5 and the bending forming mechanism 4 alternately complete the welding of the cross position of the transverse reinforcement 61 and the longitudinal reinforcement 62 and the bending forming of the transverse reinforcement 61, the formed part of the reinforcement can be fixed and kept consistent with the set shape of the forming core mould 12, the formed shape of the previous time cannot be influenced during the next time of forming, and the forming quality of the hoop reinforcement 63 is further ensured. The steel reinforcement cage welding set overall structure of this embodiment is simple, compact, goes out hoop reinforcement 63 when the shaping and fixes hoop reinforcement 63 welded fastening on longitudinal reinforcement 62, need not manual placing, and degree of automation is high, and production efficiency is high.

Further, in this embodiment, the lateral side of the welding mechanism 5 is further provided with a transverse reinforcement feeding mechanism 21 and a transverse reinforcement shearing mechanism 22, that is, the transverse reinforcement feeding mechanism 21 drives the transverse reinforcement 61 to move transversely to realize automatic feeding, when a set length is reached, the welding mechanism 5 welds and fixes the transverse reinforcement 61 and the longitudinal reinforcement 62, and finally the transverse reinforcement shearing mechanism 22 shears the transverse reinforcement 61, so that the automation degree and the production efficiency of the device are further improved. Of course, in other embodiments, the transverse reinforcement 61 may be cut to a predetermined length and then manually added, which is still advantageous compared to the solution in which the annular stirrup 63 is separately formed. The transverse reinforcing bar feeding mechanism 21 can be driven and fed by means of a pair roller, a chain plate and the like.

Further, in this embodiment, the rack 1 is further provided with a longitudinal steel bar shearing mechanism 31, and the longitudinal steel bar shearing mechanism 31 and the forming core mold 12 are respectively disposed at two ends of the rack 1. When the reinforcement cage 6 needs to be segmented, the longitudinal reinforcement shearing mechanism 31 can shear the reinforcement cage 6 to a required length. The existing scheme can be adopted for shearing, automatic welding and the like of the reinforcement cage, and the specific structure is not repeated.

Further, in the present embodiment, the frame 1 is provided with a lifting mechanism 32 (such as an air cylinder, an oil cylinder, an electric push rod, etc.), and the longitudinal bar shearing mechanism 31 is provided on the lifting mechanism 32. To the condition that the reinforcement cage 6 does not need to be cut, the lifting mechanism 32 drives the longitudinal reinforcement cutting mechanism 31 to descend, so that the influence on the longitudinal feeding of the reinforcement cage 6 is avoided, and the structure is simple and effective.

As a preferred embodiment, bend forming mechanism 4 is coupled to welding mechanism 5 for synchronous movement along longitudinal rails 11, facilitating control of the reciprocating movement of bend forming mechanism 4 and welding mechanism 5 and reducing the number of drive components required for longitudinal movement. Of course, in other embodiments, the bending forming mechanism 4 and the welding mechanism 5 may be independent structures, and are driven by the driving part to reciprocate along the longitudinal rail 11.

Further, in the present embodiment, the bending and forming mechanism 4 includes a first mounting seat 45 provided on the longitudinal rail 11, and an elevation driving member 41 and a lateral movement driving member 42 provided on the first mounting seat 45, first forming members 43 for bending the lateral reinforcing bars 61 are provided on both left and right sides below the forming core 12, second forming members 44 are provided on both left and right sides above the forming core 12, the elevation driving member 41 is connected to the first forming members 43, and the lateral movement driving member 42 is connected to the second forming members 44. After the first mounting block 45 has been moved into position, the first forming section 43 below the forming core 12 is located below the transverse reinforcing bars 61. Then the lifting driving part 41 drives the first forming part 43 to rise, the first forming part 43 is matched with the forming core mould 12 to initially bend the transverse steel bars 61 into a U shape, then after the first mounting seat 45 is put in place again, the transverse moving driving part 42 drives the second forming parts 44 on the left side and the right side above the forming core mould 12 to approach towards the middle, the second forming parts 44 are matched with the forming core mould 12, and the U-shaped transverse steel bars 61 are further bent into annular stirrups 63. After the operation is completed, the lifting driving component 41 and the transverse moving driving component 42 respectively drive the first forming component 43 and the second forming component 44 to reset, the longitudinal steel bar 62 moves for a set distance along the longitudinal direction (i.e. the length direction), and the above processes are repeated, so that the whole steel bar cage 6 can be formed in a circulating manner (the concrete structure after the formed steel bar cage 6 is separated from the forming core mold 12 is shown in fig. 8d and 9). The bending forming mechanism 4 is simple and compact in structure, smooth in action and high in bending forming efficiency.

In a preferred embodiment, the elevation driving member 41 has a telescopic structure and is provided below the forming core 12.

Specifically, the lifting driving component 41 may be, for example, an air cylinder, an oil cylinder, an electric push rod, or the like, and the number of the lifting driving components may be one and simultaneously drive the two first forming components 43, or may be two and respectively drive the two first forming components 43, which is not described again.

In a preferred embodiment, the traverse driving member 42 has a telescopic structure and is provided in two pieces, the two traverse driving members 42 are disposed opposite to each other on the left and right sides of the forming core 12, and the second forming member 44 located on the same side of the forming core 12 is connected to the traverse driving member 42.

Specifically, the traverse driving member 42 may be, for example, an air cylinder, an oil cylinder, or an electric push rod, which will not be described in detail.

Further, in the present embodiment, a guiding mechanism is provided between each of the first molding member 43 and the second molding member 44 and the frame 1. The guide mechanism can provide a guide function, can prevent the first forming part 43 and the second forming part 44 from shifting in the moving process, and has a simple and effective structure.

Specifically, the guide mechanism may include, for example, a guide rail and a slider engaged with the guide rail; or the guide mechanism comprises a guide rail and a pulley matched with the guide rail; or, the guide mechanism comprises a guide groove and a slide block matched with the guide groove, and the like, which are not described in detail.

In the present embodiment, the first molding member 43 and the second molding member 44 are both molding rolls. The friction force between the forming roller and the transverse steel bar 61 in the relative movement process can be reduced, the abrasion of the parts is reduced, and meanwhile, the driving force required by the lifting driving part 41 and the transverse moving driving part 42 can also be reduced. Of course, in other embodiments, the first forming member 43 and the second forming member 44 may also be formed blocks, etc., and the contact position with the transverse reinforcing bar 61 is a bevel or a fillet structure, which has disadvantages of large wear and large driving force.

Furthermore, in this embodiment, two sides of the forming roller are provided with a limiting flange. Set up limit flange and be favorable to preventing that position from taking place the skew behind the transverse reinforcement 61 atress, if limit flange on the shaping gyro wheel of both sides staggers, can make transverse reinforcement 61 coincident part at last stagger to overlap joint is interfered about taking place transverse reinforcement 61 both ends, influences the shaping quality, simple structure, effective.

Further, in the present embodiment, the longitudinal reinforcing bar positioning member 13 is a positioning sleeve. After the longitudinal reinforcing bar 62 penetrates the positioning sleeve, the position deviation can be effectively prevented, and the positioning sleeve can also provide a good guiding effect when the longitudinal reinforcing bar 62 moves along the longitudinal direction.

Further, in this embodiment, the longitudinal feeding mechanism 7 includes a second mounting seat 71 disposed on the longitudinal rail 11 and a reinforcement cage holding mechanism 72 disposed on the second mounting seat 71. When the reinforcement cage 6 needs to move longitudinally, the reinforcement cage is clamped and fixed by the reinforcement cage clamping mechanism 72 (various mechanisms capable of fixing or releasing the reinforcement cage 6 are all available), and then the second mounting seat 71 drives the reinforcement cage clamping mechanism 72 to move longitudinally. The first and second mounting seats 45 and 71 can reciprocate along the longitudinal guide rail 11 by an air cylinder, an oil cylinder, or an electric push rod.

Example two

Fig. 8 to 9 show an embodiment of the welding method of the reinforcement cage welding device, which includes the following steps:

s1, positioning a reinforcement cage 6: the longitudinal feeding mechanism 7 drives the reinforcement cage 6 to move for a set distance along the longitudinal guide rail 11;

s2, primary welding of the transverse steel bars 61: the welding mechanism 5 welds and fixes the crossing portions of the transverse steel bars 61 and the longitudinal steel bars 62 (specifically, as shown in fig. 8a, the transverse steel bars 61 and the two longitudinal steel bars 62 on the lower side are welded and fixed; in other embodiments, the transverse steel bars 61 and the two longitudinal steel bars 62 on the upper side can also be welded and fixed, or the cross-sectional shape of the steel reinforcement cage 6 can be adjusted correspondingly, in this embodiment, the transverse steel bar feeding mechanism 21 drives the transverse steel bars 61 to move transversely to realize automatic feeding, when the set length is reached, the welding mechanism 5 welds and fixes the transverse steel bars 61 and the longitudinal steel bars 62, and then the transverse steel bar shearing mechanism 22 shears the transverse steel bars 61, so that the automation degree and the production efficiency are further improved;

s3, primarily bending the transverse steel bar 61: the welding mechanism 5 moves along the longitudinal guide rail 11 for a set distance to be separated from the transverse steel bars 61, and the bending forming mechanism 4 moves to the position of the transverse steel bars 61 and preliminarily bends the transverse steel bars 61 (as shown in fig. 8 b);

s4, welding the transverse steel bars 61 again: the bending forming mechanism 4 moves to an initial position to be separated from the transverse steel bars 61, the welding mechanism 5 moves to the initial position and welds and fixes the intersection positions of the bent parts of the transverse steel bars 61 and the longitudinal steel bars 62 (specifically, as shown in fig. 8b, the transverse steel bars 61 and the two longitudinal steel bars 62 on the upper side are welded and fixed);

s5, bending the transverse steel bars 61 again: the welding mechanism 5 moves along the longitudinal guide rail 11 for a set distance to be separated from the transverse steel bar 61, and the bending forming mechanism 4 moves to the position of the transverse steel bar 61 and bends the transverse steel bar 61 again (as shown in fig. 8c and 8d, in this embodiment, the transverse steel bar 61 is bent twice to obtain a hoop reinforcement 63 with a rectangular cross section);

s6, if the transverse steel bars 61 are already bent into the hoop reinforcements 63, executing the step S7; if the transverse steel bars 61 are not bent into the hoop reinforcements 63, repeating the steps S4 to S5 until the transverse steel bars 61 are bent into the hoop reinforcements 63 (in this embodiment, the hoop reinforcements 63 are rectangular, and are formed after being bent twice in the steps S3 and S5, although in other embodiments, when the shape of the hoop reinforcements 63 changes, for example, when the shape of the hoop reinforcements 63 changes, the bending mode and the number of times are correspondingly adjusted, for example, when the hoop reinforcements 63 are regular hexagonal, the hoop reinforcements can be formed;

and S7, repeating the steps from S1 to S6 until the reinforcement cage 6 is welded.

In the welding method disclosed in this embodiment, the longitudinal feeding mechanism 7 drives the reinforcement cage 6 to move longitudinally, the welding mechanism 5 and the bending forming mechanism 4 alternately complete the welding of the cross positions of the transverse reinforcements 61 and the longitudinal reinforcements 62 and the bending forming of the transverse reinforcements 61 along the reciprocating movement of the longitudinal guide rail 11, the formed part of the reinforcements can be fixed and kept consistent with the set shape of the forming core mold 12, the formed shape of the previous time cannot be affected during the next forming, and the forming quality of the hoop reinforcement 63 is further ensured, the hoop reinforcement 63 is welded and fixed on the longitudinal reinforcements 62 while the hoop reinforcement 63 is formed, the manual placement is not needed, the automation degree is high, and the production efficiency is high.

In other embodiments, the welding and bending steps can be replaced, that is, the transverse steel bar 61 is subjected to primary bending, primary welding, secondary bending and secondary welding \8230insequence until the transverse steel bar 61 is bent into the hoop reinforcement 63.

Although the present invention has been described with reference to the preferred embodiments, it is not intended to limit the present invention. The technical solution of the present invention can be used by anyone skilled in the art to make many possible variations and modifications, or to modify equivalent embodiments, without departing from the scope of the present invention, using the technical content disclosed above. Therefore, any simple modification, equivalent change and modification made to the above embodiments by the technical entity of the present invention should fall within the protection scope of the technical solution of the present invention.

Claims (9)

1. The utility model provides a steel reinforcement cage welding set which characterized in that: including frame (1), be equipped with longitudinal rail (11), shaping mandrel (12) and longitudinal reinforcement locating part (13) on frame (1), longitudinal reinforcement locating part (13) are located shaping mandrel (12) are all around, be equipped with bending forming mechanism (4), welding mechanism (5) on longitudinal rail (11) and be used for driving longitudinal feed mechanism (7) of longitudinal movement along steel reinforcement cage (6).

2. The reinforcement cage welding apparatus of claim 1, wherein: the side edge of the welding mechanism (5) is also provided with a transverse steel bar feeding mechanism (21) and a transverse steel bar shearing mechanism (22).

3. A reinforcement cage welding apparatus as set forth in claim 1, wherein: the steel bar shearing machine is characterized in that a longitudinal steel bar shearing mechanism (31) is further arranged on the rack (1), and the longitudinal steel bar shearing mechanism (31) and the forming core mold (12) are respectively arranged at two ends of the rack (1).

4. A reinforcement cage welding apparatus as set forth in claim 3, wherein: the machine frame (1) is provided with a lifting mechanism (32), and the longitudinal steel bar shearing mechanism (31) is arranged on the lifting mechanism (32).

5. A reinforcement cage welding apparatus as set forth in claim 1, wherein: the bending forming mechanism (4) is connected with the welding mechanism (5) to synchronously move along the longitudinal guide rail (11).

6. A reinforcement cage welding apparatus as claimed in any one of claims 1 to 5, wherein: the bending forming mechanism (4) comprises a first mounting seat (45) arranged on a longitudinal guide rail (11), a lifting driving part (41) and a transverse moving driving part (42) arranged on the first mounting seat (45), first forming parts (43) used for bending transverse reinforcing steel bars (61) are arranged on the left side and the right side below a forming core mold (12), second forming parts (44) are arranged on the left side and the right side above the forming core mold (12), the lifting driving part (41) is connected with the first forming parts (43), and the transverse moving driving part (42) is connected with the second forming parts (44).

7. The reinforcement cage welding apparatus of claim 6, wherein: the lifting driving part (41) is of a telescopic structure and is arranged below the forming core mould (12), the transverse moving driving part (42) is of a telescopic structure and is provided with two parts, the two transverse moving driving parts (42) are oppositely arranged at the left side and the right side of the forming core mould (12), and the second forming part (44) positioned at the same side of the forming core mould (12) is connected with the transverse moving driving part (42).

8. A reinforcement cage welding apparatus as claimed in any one of claims 1 to 5, wherein: the longitudinal steel bar positioning part (13) is a positioning sleeve.

9. A reinforcement cage welding apparatus as claimed in any one of claims 1 to 5, wherein: the longitudinal feeding mechanism (7) comprises a second mounting seat (71) arranged on the longitudinal guide rail (11) and a reinforcement cage clamping mechanism (72) arranged on the second mounting seat (71).

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