CN210731439U

CN210731439U - Feeding structure of pipe joint welding equipment

Info

Publication number: CN210731439U
Application number: CN201921860761.9U
Authority: CN
Inventors: 吕鸿钧; 林尚雷; 黄乐军; 吕鸿雁; 黄勇军
Original assignee: Foshan Yuanyuan Automation Equipment Technology Co Ltd
Current assignee: Foshan Yuanyuan Automation Equipment Technology Co Ltd
Priority date: 2019-07-17
Filing date: 2019-10-31
Publication date: 2020-06-12
Anticipated expiration: 2029-10-31
Also published as: CN210731516U; CN210731529U

Abstract

The utility model relates to a coupling welding equipment's pay-off structure, including first coupling sequencing shake dish, second coupling sequencing shake dish and coupling biography guide slot, the coupling conduction groove passes the guide slot including setting up side by side at first transmission slot and second, the one end of first transmission slot and the delivery outlet switch-on of first coupling sequencing shake dish, the one end that the guide slot was passed to the second and the delivery outlet switch-on of second coupling sequencing shake dish, the other end of first transmission slot and the other end that the guide slot was passed to the second are drawn together each other and are connected with the unloading elbow, the unloading elbow is equipped with two passageways, the one end of two passageways communicates with first transmission slot and second conduction slot one by one respectively, the other end of two passageways is down. The utility model discloses export two work pieces that need the welded to being close to together and can improve welding process's efficiency.

Description

Feeding structure of pipe joint welding equipment

Technical Field

The utility model relates to a coupling welding equipment, especially a coupling welding equipment's pay-off structure.

Background

The metal joint is a part commonly used in air conditioning systems, water channel systems and other systems, wherein, taking the metal joint with two ends with different diameters as an example, the metal joint basically needs two pipes with different diameters to be welded together to form the metal joint. The existing pipe joint welding equipment adopts manual feeding and clamping, and the working efficiency is low.

Disclosure of Invention

An object of the utility model is to provide a simple structure is reasonable, the orderly coupling automatic weld equipment of work piece proper motion arrangement.

The purpose of the utility model is realized like this:

the utility model provides a pipe joint welding equipment's pay-off structure, includes that first pipe joint sequencing shakes the dish, second pipe joint sequencing shakes dish and pipe joint biography guide slot, its characterized in that: the pipe joint conducting groove comprises a first conducting groove and a second conducting groove which are arranged side by side, one end of the first conducting groove is communicated with an output port of a first pipe joint sequencing vibration disc, one end of the second conducting groove is communicated with an output port of a second pipe joint sequencing vibration disc, the other end of the first conducting groove and the other end of the second conducting groove are mutually closed and connected with a blanking elbow, the blanking elbow is provided with two channels, one ends of the two channels are respectively communicated with the first conducting groove and the second conducting groove one by one, and the other ends of the two channels face downwards. When the other end of the first transmission guide groove and the other end of the second transmission guide groove are mutually closed, the two workpieces can be mutually close, the stroke and time of pressing the two workpieces after being output are reduced, the working efficiency is improved, and the splicing error is reduced. The first pipe joint sequencing vibration disc is used for placing the stainless steel outer tooth straight-through and outputting the stainless steel outer tooth straight-through to the first transmission guide groove after sequencing, and the second pipe joint sequencing vibration disc is used for placing the stainless steel inner tooth straight-through and outputting the stainless steel inner tooth straight-through to the second transmission guide groove after sequencing.

The purpose of the utility model can also adopt the following technical measures to solve:

more specifically, the pipe joint conveying groove is V-shaped.

As a further scheme, the channel of the blanking elbow is in a 7 shape, the lower end of the blanking elbow is provided with a material receiving mould in a transverse sliding mode, and the top surface of the material receiving mould is provided with a channel shielding surface and a pipe joint avoiding groove.

As a further scheme, the left side and the right side of the pipe joint avoidance groove are respectively provided with a first ejection rotating shaft and a second ejection rotating shaft, the first ejection rotating shaft and the second ejection rotating shaft are respectively arranged in a longitudinal sliding mode, the first ejection rotating shaft and the second ejection rotating shaft are arranged concentrically, and the first ejection rotating shaft or the second ejection rotating shaft is in transmission connection with a driving motor.

As a further scheme, the pipe joint welding equipment comprises a rack assembly, wherein the blanking elbow and the rack assembly are relatively static, the material receiving mold is arranged on the rack assembly in a transverse sliding mode, and the first material ejecting rotating shaft and the second material ejecting rotating shaft are arranged on the rack assembly in a longitudinal sliding mode.

As a further scheme, a welding gun support is arranged on the rack assembly, a welding gun is arranged on the welding gun support, and the welding gun is located above the material receiving mold.

The utility model has the advantages as follows:

the utility model discloses export two work pieces that need the welded to being close to together and can improve welding process's efficiency.

Drawings

Fig. 1 is a schematic view of a partial structure according to an embodiment of the present invention.

Fig. 2 is an enlarged schematic view of a portion a in fig. 1.

Fig. 3 is a schematic structural view of the welded workpiece (metal joint) according to the present invention.

Fig. 4 is a schematic view of an angle structure of the present invention.

Fig. 5 is a schematic view of the local position overlooking structure of the present invention.

FIG. 6 is a schematic sectional view of the structure of FIG. 5B-B.

Fig. 7 is a schematic structural view of another working state of fig. 5.

FIG. 8 is a schematic cross-sectional view of the structure of FIG. 7C-C.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and examples.

Referring to fig. 1, 2, 4 and 5, a feeding structure of a pipe joint welding device comprises a first pipe joint sorting seismic disc 11, a second pipe joint sorting seismic disc 12 and a pipe joint transmission groove, wherein the pipe joint transmission groove comprises a first transmission groove 13 and a second transmission groove 14 which are arranged side by side, one end of the first transmission groove 13 is communicated with an output port of the first pipe joint sorting seismic disc 11, one end of the second transmission groove 14 is communicated with an output port of the second pipe joint sorting seismic disc 12, the other end of the first transmission groove 13 and the other end of the second transmission groove 14 are mutually closed and connected with a blanking elbow 15, the blanking elbow 15 is provided with two channels, one ends of the two channels are respectively communicated with the first transmission groove 13 and the second transmission groove 14 one by one, and the other ends of the two channels face downwards.

The pipe joint transmission and guide groove is V-shaped.

The channel of the blanking elbow 15 is in a 7 shape, the lower end of the blanking elbow is provided with a receiving mould in a transverse sliding mode, and the top surface of the receiving mould is provided with a channel shielding surface and a pipe joint avoiding groove 24.

The lower end of the blanking elbow 15 is a discharge hole, and the material receiving mould is positioned below the discharge hole.

The material receiving die comprises a front die 21 and a rear die 22, wherein notches are respectively arranged on the opposite sides of the front die 21 and the rear die 22, the notch of the front die 21 and the notch of the rear die 22 jointly form a pipe joint avoiding groove 24, the top surface of the pipe joint avoiding groove 24 is open, the top surface of the front die 21 is provided with a channel shielding surface, and the channel shielding surface (top surface) is used for shielding a discharge hole of a pipe joint transmission and guide groove; the front mold 21 and the rear mold 22 are respectively arranged on the rack assembly in a transverse sliding mode.

A transverse linear guide rail 23 is arranged on the rack assembly, a front sliding plate 211 and a rear sliding plate 221 are respectively arranged on the transverse linear guide rail 23 in a sliding manner, a front mold 21 is arranged on the front sliding plate 211, and a rear mold 22 is arranged on the rear sliding plate 221; the rear sliding plate 221 is in transmission connection with the workpiece loading and unloading cylinder 3; a baffle plate 91 is arranged in front of the rack assembly corresponding to the front sliding plate 211, and a spring 92 is arranged between the baffle plate 91 and the front sliding plate 211.

The front end of the front sliding plate 211 is provided with a guide rod 93, the guide rod 93 penetrates through the baffle plate 91, and the spring 92 is sleeved outside the guide rod 93.

A first material ejecting rotating shaft 5 and a second material ejecting rotating shaft 4 are respectively arranged on the left side and the right side of the material receiving mould, the first material ejecting rotating shaft 5 and the second material ejecting rotating shaft 4 are respectively arranged on the rack assembly in a longitudinal linear sliding mode, the first material ejecting rotating shaft 5 and the second material ejecting rotating shaft 4 are concentrically arranged, and the first material ejecting rotating shaft 5 is in transmission connection with a driving motor 54; and a welding gun support 7 is arranged on the rack assembly, a welding gun 71 is arranged on the welding gun support 7, and the welding gun 71 is positioned above the material receiving mold.

And the centers of the opposite ends of the first ejection rotating shaft 5 and the second ejection rotating shaft 4 are respectively provided with a first pipe joint centering mandril 55 and a second pipe joint centering mandril 44, and the outer ends of the first pipe joint centering mandril 55 and the second pipe joint centering mandril 44 are respectively provided with a limiting step.

A first longitudinal linear guide rail 52 and a second longitudinal linear guide rail 42 are respectively arranged on the left side and the right side of the rack assembly corresponding to the material receiving mold, a first supporting plate 53 is longitudinally arranged on the first longitudinal linear guide rail 52 in a sliding manner, a first material ejecting rotating shaft 5 is rotatably arranged on the first supporting plate 53, the first supporting plate 53 is also provided with a driving motor 54, and the driving motor 54 is in transmission connection with the first material ejecting rotating shaft 5; the rack assembly is provided with a first material ejecting cylinder 51, and the first material ejecting cylinder 51 is used for pushing a first supporting plate 53.

And a second supporting plate 43 is longitudinally arranged on the second longitudinal linear guide rail 42 in a sliding manner, the second material ejecting rotating shaft 4 is rotatably arranged on the second supporting plate 43, a second material ejecting cylinder 41 is arranged on the rack assembly, and the second material ejecting cylinder 41 is used for pushing the second supporting plate 43.

And a limit stop 61 is arranged at the rear part of the rear die 22, a guide seat 62 is arranged on the rack assembly, the limit stop 61 is longitudinally arranged on the guide seat 62 in a sliding manner, and the guide seat is in transmission connection with the limit cylinder 6.

The rack assembly comprises a main rack 20 and an auxiliary rack 30, wherein a bottom plate 10 is arranged on the main rack 20, a material receiving mold is arranged on the bottom plate 10, the auxiliary rack 30 is arranged in front of the main rack 20, and a first pipe joint sequencing seismic disk 11 and a second pipe joint sequencing seismic disk 12 are arranged on the auxiliary rack 30.

As described with reference to fig. 3, the machined pipe joint 8 is formed by welding two workpieces, namely, a stainless steel outer thread through 81 and a stainless steel inner thread through 82, and the position 83 in fig. 3 is the welding position of the two workpieces. The first pipe joint sequencing vibration disc 11 is used for placing the stainless steel outer tooth through 81 and outputting the stainless steel outer tooth through 81 to the first transmission guide groove 13 after sequencing, and the second pipe joint sequencing vibration disc 12 is used for placing the stainless steel inner tooth through 82 and outputting the stainless steel inner tooth through 82 to the second transmission guide groove 14 after sequencing.

The working principle is as follows: in the initial state, the channel shielding surface of the front mold 21 blocks the lower port (feed opening) of the feed elbow 15, and the rear mold 22 is separated from the front mold 21 by a certain distance, which can refer to the state shown in fig. 5 and 6; referring to fig. 7 and 8, when welding is performed by charging, the workpiece loading and unloading cylinder 3 pushes the rear die 22 forward, the rear die 22 is pushed forward after contacting with the front die 21 in the forward process, the front die 21 is pushed to advance together until the pipe joint avoiding groove 24 is aligned with a feed opening, the stainless steel outer tooth through 81 and the stainless steel inner tooth through 82 respectively fall into the pipe joint avoiding groove 24, at this time, the spring 92 between the front die 21 and the baffle plate 91 is compressed to a certain degree, and the limit cylinder 6 drives the limit stop 61 to extend to the rear of the rear die 22; then, the workpiece loading and unloading cylinder 2 drives the rear die 22 to retreat, and simultaneously, the spring 92 releases the elasticity thereof, so that the front die 21 retreats along with the rear die 22 until the rear die 22 is blocked by the limit stop 61, and the workpiece loading and unloading cylinder 2 also stops; at the moment, the stainless steel outer tooth through 81 and the stainless steel inner tooth through 82 are located at positions opposite to the first pipe joint centering ejector rod 55 and the second pipe joint centering ejector rod 44, the first ejector cylinder 51 and the second ejector cylinder 41 are started, the first pipe joint centering ejector rod 55 and the second pipe joint centering ejector rod 44 are respectively inserted into the stainless steel outer tooth through 81 and the stainless steel inner tooth through 82, so that the stainless steel outer tooth through 81 and the stainless steel inner tooth through 82 are concentric, and opposite end faces of the stainless steel outer tooth through 81 and the stainless steel inner tooth through 82 are aligned and pressed; then, welding the contact position of the stainless steel outer tooth straight-through 81 and the stainless steel inner tooth straight-through 82 by using a welding gun 71, starting a driving motor 54 during welding, driving the stainless steel outer tooth straight-through 81 and the stainless steel inner tooth straight-through 82 to rotate simultaneously until the contact positions of the stainless steel outer tooth straight-through 81 and the stainless steel inner tooth straight-through 82 are completely welded and sealed, and completing welding processing of the pipe joint 8; finally, the first knock cylinder 51, the second knock cylinder 41, and the stopper cylinder 6 are reset, and then, the workpiece mounting and demounting cylinder 2 is further reset to retreat, so that the rear die 22 is spaced apart from the front die 21 (returning to the state shown in fig. 5 and 6), and the pipe joint 8 falls down from between the rear die 22 and the front die 21. In this embodiment, the main rack 20 is provided with a discharge channel below the position where the rear mold 22 and the front mold 21 are separated, the discharge channel leads to the rack assembly, a collecting tank is arranged outside the rack assembly, and the processed pipe joint 8 falls into the collecting tank along the discharge channel for recycling.

Claims

1. The utility model provides a pipe joint welding equipment's pay-off structure, passes the guide slot including first pipe joint sequencing shake dish (11), second pipe joint sequencing shake dish (12) and pipe joint, its characterized in that: the pipe joint conducting groove comprises a first conducting groove (13) and a second conducting groove (14) which are arranged side by side, one end of the first conducting groove (13) is communicated with an output port of a first pipe joint sequencing vibration disc (11), one end of the second conducting groove (14) is communicated with an output port of a second pipe joint sequencing vibration disc (12), the other end of the first conducting groove (13) and the other end of the second conducting groove (14) are mutually closed and connected with a blanking elbow (15), the blanking elbow (15) is provided with two channels, one ends of the two channels are respectively communicated with the first conducting groove (13) and the second conducting groove (14) one by one, and the other ends of the two channels face downwards.

2. The feeding structure of the pipe joint welding apparatus as set forth in claim 1, wherein: the pipe joint transmission and guide groove is V-shaped.

3. The feeding structure of the pipe joint welding apparatus as set forth in claim 1, wherein: the channel of the blanking elbow (15) is in a 7 shape, the lower end of the blanking elbow is provided with a material receiving mould in a transverse sliding mode, and the top surface of the material receiving mould is provided with a channel shielding surface and a pipe joint avoiding groove (24).

4. The feeding structure of the pipe joint welding apparatus as set forth in claim 3, wherein: the left side and the right side of the pipe joint avoidance groove (24) are respectively provided with a first ejection rotating shaft (5) and a second ejection rotating shaft (4), the first ejection rotating shaft (5) and the second ejection rotating shaft (4) are respectively arranged in a longitudinal sliding mode, the first ejection rotating shaft (5) and the second ejection rotating shaft (4) are arranged concentrically, and the first ejection rotating shaft (5) or the second ejection rotating shaft (4) is in transmission connection with a driving motor (54).

5. The feeding structure of the pipe joint welding apparatus as set forth in claim 4, wherein: the pipe joint welding equipment comprises a rack assembly, wherein a blanking elbow (15) and the rack assembly are relatively static, a material receiving mould is arranged on the rack assembly in a transverse sliding mode, and a first ejection rotating shaft (5) and a second ejection rotating shaft (4) are arranged on the rack assembly in a longitudinal sliding mode.

6. The feeding structure of the pipe joint welding apparatus as set forth in claim 5, wherein: be equipped with welder support (7) on the rack assembly, welder support (7) are equipped with and set up welder (71), and welder (71) are located and connect material mould top.