CN112372190A - Boiler factory pin welding feeding system - Google Patents
Boiler factory pin welding feeding system Download PDFInfo
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- CN112372190A CN112372190A CN202011369827.1A CN202011369827A CN112372190A CN 112372190 A CN112372190 A CN 112372190A CN 202011369827 A CN202011369827 A CN 202011369827A CN 112372190 A CN112372190 A CN 112372190A
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- 238000003466 welding Methods 0.000 title claims abstract description 28
- 239000000463 material Substances 0.000 claims abstract description 207
- 230000007246 mechanism Effects 0.000 claims abstract description 59
- 238000005192 partition Methods 0.000 claims description 48
- 230000000903 blocking effect Effects 0.000 claims description 30
- 238000007599 discharging Methods 0.000 claims description 22
- 238000007664 blowing Methods 0.000 claims description 15
- 230000007704 transition Effects 0.000 claims description 15
- CTJBHIROCMPUKL-UHFFFAOYSA-N butoxycarboxim Chemical compound CNC(=O)ON=C(C)C(C)S(C)(=O)=O CTJBHIROCMPUKL-UHFFFAOYSA-N 0.000 claims description 7
- 230000000694 effects Effects 0.000 claims description 2
- 239000013589 supplement Substances 0.000 abstract description 6
- 230000009471 action Effects 0.000 description 2
- 238000009434 installation Methods 0.000 description 2
- 238000010079 rubber tapping Methods 0.000 description 2
- 230000005484 gravity Effects 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000001737 promoting effect Effects 0.000 description 1
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23K—SOLDERING OR UNSOLDERING; WELDING; CLADDING OR PLATING BY SOLDERING OR WELDING; CUTTING BY APPLYING HEAT LOCALLY, e.g. FLAME CUTTING; WORKING BY LASER BEAM
- B23K37/00—Auxiliary devices or processes, not specially adapted to a procedure covered by only one of the preceding main groups
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- Optics & Photonics (AREA)
- Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- Dovetailed Work, And Nailing Machines And Stapling Machines For Wood (AREA)
- Portable Nailing Machines And Staplers (AREA)
Abstract
A pin welding feeding system for a boiler factory comprises a rack, a feeding assembly and a rapid nail feeding mechanism which are arranged on the rack, and a material pipeline for connecting the feeding assembly and the rapid nail feeding mechanism; the rapid nail feeding mechanism is positioned below the feeding assembly; the feeding assembly comprises a stock bin and a nail selecting and feeding mechanism; a discharge opening is formed in one side of the bottom of the storage bin, and the nail selecting and feeding mechanism is arranged close to the discharge opening; the nail selecting and feeding mechanism comprises a feeding support and a multi-stage ejection mechanism movably arranged on the feeding support. Therefore, the successful probability of material ejection can be improved, the working efficiency is improved, and quick material supplement is realized.
Description
Technical Field
The invention relates to the technical field of welding equipment, in particular to a pin welding feeding system in a boiler plant.
Background
The boiler factory pins are straight pins, namely, the large head end and the small head end are not provided. When feeding straight pins to a welding gun, straight pins parallel to the material channel need to be selected and fed into the material channel. The conventional feeding mechanism with one ejector plate has low material selection success rate and low feeding efficiency; in addition, the speed of the straight pin entering the welding gun is low, and the requirement of quick material supplement cannot be met.
Disclosure of Invention
In view of the above, the invention provides a boiler plant pin welding feeding system which improves the probability of successful material ejection, improves the working efficiency and realizes rapid material supplement, so as to solve the above problems.
A pin welding feeding system for a boiler factory comprises a rack, a feeding assembly and a rapid nail feeding mechanism which are arranged on the rack, a material channel pipe for connecting the feeding assembly and the rapid nail feeding mechanism, a connecting hose and a welding gun; the rapid nail feeding mechanism is positioned below the feeding assembly; the feeding assembly comprises a stock bin and a nail selecting and feeding mechanism; a discharge opening is formed in one side of the bottom of the storage bin, and the nail selecting and feeding mechanism is arranged close to the discharge opening; the nail selecting and feeding mechanism comprises a feeding support and a multi-stage ejection mechanism movably arranged on the feeding support; the connecting hose is connected with the quick nail feeding mechanism and the welding gun; the feeding support is provided with two side plates which are oppositely arranged and a middle plate which is connected with the bottoms of the two side plates, a plurality of partition plates are arranged between the two side plates at intervals above the middle plate, the heights of the plurality of partition plates which are arranged on the feeding support are gradually increased from one side close to the discharging opening to one side far away from the discharging opening, first gaps are formed between every two adjacent partition plates and between each partition plate and the middle plate, the top of one side plate is provided with a discharging opening, a transition pipe is arranged on the outer side of the discharging opening, and a second material sensor is arranged on each transition pipe; the multistage ejection mechanism comprises an ejection cylinder, a movable material channel plate connected with an output shaft of the ejection cylinder and a plurality of ejection plates which are sequentially connected, wherein the ejection plate closest to the movable material channel plate is connected with the movable material channel plate, the arrangement heights of the plurality of ejection plates are gradually reduced from one side close to the movable material channel plate to one side far away from the movable material channel plate, the ejection plates are movably positioned in the first gap, and the movable material channel plate is positioned on the outer side, far away from the storage bin, of the uppermost partition plate; the rapid nail feeding mechanism comprises a material transfer box, a feeding pipe and a discharging pipe which are arranged on a top plate of the material transfer box at intervals, a material transfer block which is positioned in the material transfer box in a sliding manner, a transfer cylinder and a material blocking cylinder which are used for driving the material transfer block to move; the material transfer box is provided with a top plate and a bottom plate, a first through hole and a second through hole are formed in the top plate of the material transfer box at intervals, the feeding pipe is communicated with the first through hole, the discharging pipe is communicated with the second through hole, a third through hole is formed in the middle of the material transfer block and is movably communicated with the first through hole or the second through hole, an air blowing channel is formed in the bottom plate of the material transfer box, and an air blowing outlet of the air blowing channel is formed in the top surface of the bottom plate and is opposite to the second through hole; the side surface of the feeding pipe is provided with a material blocking port, the output end of the material blocking cylinder is connected with a material blocking rod, and the material blocking rod movably extends into the feeding pipe through the material blocking port; and a controller is connected with the welding gun, the second material sensor, the transfer cylinder, the material blocking cylinder, the material ejecting cylinder and an alarm.
Furthermore, the number of the partition boards is 3, and the partition boards are respectively a first partition board, a second partition board and a third partition board; the number of the ejector plates is 3, and the ejector plates are respectively a first ejector plate, a second ejector plate and a third ejector plate, and the first ejector plate and the movable material channel plate, the first ejector plate and the second ejector plate and the third ejector plate are connected through a first connecting block; the top of activity material guidance tape board has the slope material and says that the height of slope material is from keeping away from the one end of discharge gate to the one end of orientation discharge gate reduces gradually.
Furthermore, the top surfaces of the first partition plate, the second partition plate and the third partition plate are all inclined surfaces, and the heights of the inclined surfaces are gradually reduced from one side close to the discharge opening to one side far away from the discharge opening.
Furthermore, a baffle is arranged at the top of one side, away from the ejector plate, of the movable material channel plate, and the baffle protrudes upwards from the inclined material channel.
Furthermore, a sliding block is arranged on one side, away from the movable material channel plate, of the ejector plate, away from the movable material channel plate, a guide rail is arranged on one side, facing the ejector cylinder, of the intermediate plate, and the sliding block is connected with the guide rail in a sliding mode.
Further, the bottom of feed bin has the slope, and the ejection of compact opening is located the bottom on slope, and the feed bin is provided with first material inductor in ejection of compact opening's top.
Furthermore, one side of the discharge port, which is far away from the transition pipe, is obliquely provided with an intermediate material channel communicated with the discharge port; the end of the middle material channel close to the discharge hole is flush with the discharge hole, and the end far away from the discharge hole is higher than the discharge hole.
Compared with the prior art, the boiler factory pin welding feeding system comprises a rack, a feeding assembly and a rapid nail feeding mechanism which are arranged on the rack, a material channel pipe for connecting the feeding assembly and the rapid nail feeding mechanism, a connecting hose and a welding gun; the rapid nail feeding mechanism is positioned below the feeding assembly; the feeding assembly comprises a stock bin and a nail selecting and feeding mechanism; a discharge opening is formed in one side of the bottom of the storage bin, and the nail selecting and feeding mechanism is arranged close to the discharge opening; the nail selecting and feeding mechanism comprises a feeding support and a multi-stage ejection mechanism movably arranged on the feeding support; the connecting hose is connected with the quick nail feeding mechanism and the welding gun; the feeding support is provided with two side plates which are oppositely arranged and a middle plate which is connected with the bottoms of the two side plates, a plurality of partition plates are arranged between the two side plates at intervals above the middle plate, the heights of the plurality of partition plates which are arranged on the feeding support are gradually increased from one side close to the discharging opening to one side far away from the discharging opening, first gaps are formed between every two adjacent partition plates and between each partition plate and the middle plate, the top of one side plate is provided with a discharging opening, a transition pipe is arranged on the outer side of the discharging opening, and a second material sensor is arranged on each transition pipe; the multistage ejection mechanism comprises an ejection cylinder, a movable material channel plate connected with an output shaft of the ejection cylinder and a plurality of ejection plates which are sequentially connected, wherein the ejection plate closest to the movable material channel plate is connected with the movable material channel plate, the arrangement heights of the plurality of ejection plates are gradually reduced from one side close to the movable material channel plate to one side far away from the movable material channel plate, the ejection plates are movably positioned in the first gap, and the movable material channel plate is positioned on the outer side, far away from the storage bin, of the uppermost partition plate; the rapid nail feeding mechanism comprises a material transfer box, a feeding pipe and a discharging pipe which are arranged on a top plate of the material transfer box at intervals, a material transfer block which is positioned in the material transfer box in a sliding manner, a transfer cylinder and a material blocking cylinder which are used for driving the material transfer block to move; the material transfer box is provided with a top plate and a bottom plate, a first through hole and a second through hole are formed in the top plate of the material transfer box at intervals, the feeding pipe is communicated with the first through hole, the discharging pipe is communicated with the second through hole, a third through hole is formed in the middle of the material transfer block and is movably communicated with the first through hole or the second through hole, an air blowing channel is formed in the bottom plate of the material transfer box, and an air blowing outlet of the air blowing channel is formed in the top surface of the bottom plate and is opposite to the second through hole; the side surface of the feeding pipe is provided with a material blocking port, the output end of the material blocking cylinder is connected with a material blocking rod, and the material blocking rod movably extends into the feeding pipe through the material blocking port; and a controller is connected with the welding gun, the second material sensor, the transfer cylinder, the material blocking cylinder, the material ejecting cylinder and an alarm. Therefore, the successful probability of material ejection can be improved, the working efficiency is improved, and quick material supplement is realized.
Drawings
Embodiments of the invention are described below with reference to the accompanying drawings, in which:
FIG. 1 is a schematic perspective view of a pin welding feeding system for a boiler plant according to the present invention.
Fig. 2 is a perspective view of the feed assembly of fig. 1.
Fig. 3 is a schematic perspective view of the nail selecting and feeding mechanism in fig. 2.
Fig. 4 is a disassembled schematic view of a first view angle of the staple selecting and feeding mechanism in fig. 2.
Fig. 5 is a second perspective exploded view of the staple selecting and feeding mechanism of fig. 2.
Fig. 6 is a perspective view of the rapid nail feeding mechanism in fig. 1.
Fig. 7 is a disassembled schematic view of the rapid nail feeding mechanism in fig. 1.
Detailed Description
Specific embodiments of the present invention will be described in further detail below based on the drawings. It should be understood that the description herein of embodiments of the invention is not intended to limit the scope of the invention.
Referring to fig. 1, the pin welding feeding system for a boiler plant according to the present invention includes a frame 10, a feeding assembly 20 and a fast pin feeding mechanism 30 disposed on the frame 10, and a material pipe 40 connecting the feeding assembly 20 and the fast pin feeding mechanism 30.
The quick nail feeding mechanism 30 is positioned below the feeding assembly 20.
Referring to fig. 2, the feeding assembly 20 includes a mounting base plate 21, a magazine 22 disposed on the mounting base plate 21, and a nail selecting and feeding mechanism 23. The mounting base plate 21 may be integrated with the top plate of the housing 10.
The bottom of the bin 22 has a slope 221, a discharge opening 222 is formed at one side of the bottom end of the slope 221 of the bin 22, and a first material sensor 223 is disposed above the discharge opening 222 of the bin 22.
The staple selecting and feeding mechanism 23 is arranged close to the discharge opening 222.
Referring to fig. 3 to 5, the staple selecting and feeding mechanism 23 includes a feeding frame 231, a multi-stage ejecting mechanism 232 movably disposed on the feeding frame 231, a transition pipe 233 disposed at one end of the top of the feeding frame 231, and a second material sensor 234 disposed on the transition pipe 233.
The feeding support 231 is provided with two opposite side plates 23101 and a middle plate 23102 connected with the bottoms of the two side plates 23101, a plurality of (at least two) partition plates are arranged between the two side plates 23101 above the middle plate 23102 at intervals, the heights of the plurality of partition plates, which are arranged on the feeding support 231, are gradually increased from one side close to the discharging opening 222 to one side far away from the discharging opening 222, and first gaps are formed between the adjacent partition plates and between the partition plates and the middle plate 23102.
The top of one of the side plates 23101 is provided with a discharge port 23103, and the transition pipe 233 is positioned at the outer side of the discharge port 23103 and communicated with the discharge port 23103.
An intermediate material channel 23104 communicated with the discharge port 23103 is obliquely arranged on one side of the discharge port 23103 away from the transition pipe 233. The end of the intermediate material passage 23104 close to the discharge port 23103 is flush with the discharge port 23103, and the height of the end far away from the discharge port 23103 is larger than that of the discharge port 23103.
In the present embodiment, the number of the separators is 3, and the separators are a first separator 2311, a second separator 2312, and a third separator 2313.
The top surfaces of the first partition 2311, the second partition 2312 and the third partition 2313 are all inclined surfaces 23111, and the heights of the inclined surfaces 23111 are gradually reduced from the side close to the discharge opening 222 to the side far away from the discharge opening 222.
The multi-stage material ejecting mechanism 232 comprises an ejecting cylinder 2321 installed on the installation bottom plate 21, a movable material channel plate 2322 connected with an output shaft of the ejecting cylinder 2321, and a plurality of material ejecting plates connected in sequence. The ejector plate closest to the movable material channel plate 2322 is connected to the movable material channel plate 2322, and the installation height of the ejector plates is gradually reduced from the side close to the movable material channel plate 2322 to the side far from the movable material channel plate 2322. The ejector plate is movably located in the first gap, and the movable material channel plate 2322 is located at the outer side of the uppermost partition plate far away from the bin 22.
The top of the movable material channel plate 2322 is provided with an inclined material channel 23221, and the height of the inclined material channel 23221 is gradually reduced from the end away from the discharge port 23103 to the end towards the discharge port 23103, so that the material on the inclined material channel 23221 slides into the discharge port 23103 and the transition pipe 233 along the inclined material channel 23221 under the action of gravity.
The top of one side of the movable material channel plate 2322, which is far away from the ejector plate, is provided with a baffle 23222, and the baffle 23222 protrudes upwards from the inclined material channel 23221 to prevent the material from falling to the outside.
In this embodiment, the number of the ejector plates is 3, which are respectively the first ejector plate 2323, the second ejector plate 2324 and the third ejector plate 2325, and the first ejector plate 2323 and the movable material passage plate 2322, the first ejector plate 2323 and the second ejector plate 2324, and the second ejector plate 2324 and the third ejector plate 2325 are all connected by the first connecting block 2328.
The bottom of one side of the movable material channel plate 2322, which is far away from the ejector plate, is protrudingly provided with a second connecting block 2326, and the second connecting block 2326 is connected with an output shaft of the ejector cylinder 2321.
A sliding block 2327 is arranged on one side, away from the movable material channel plate 2322, of the ejector plate (i.e., the third ejector plate 2325) away from the movable material channel plate 2322, a guide rail 2314 is arranged on one side, facing the ejector cylinder 2321, of the intermediate plate 23102, and the sliding block 2327 is in sliding connection with the guide rail 2314.
In an initial state, the top surface of the third ejector plate 2325 is flush with the bottom end of the slope 221, the top surface of the second ejector plate 2324 is flush with the bottom end of the inclined surface 23111 of the first partition plate 2311, the top surface of the first ejector plate 2323 is flush with the bottom end of the inclined surface 23111 of the second partition plate 2312, and the inclined material channel 23221 of the movable material channel plate 2322 is located below the inclined surface 23111 of the third partition plate 2313. Part of the material is located on the top surface of the third ejector plate 2325, the second ejector plate 2324, the first ejector plate 2323, the first partition 2311, the second partition 2312 and the third partition 2313.
Due to the inclined surface 23111, the material on the first partition 2311 may slide onto the second ejector plate 2324, the material on the second partition 2312 may slide onto the first ejector plate 2323, and the material on the third partition 2313 may slide onto the inclined material channel 23221 of the movable material channel plate 2322.
The material ejecting cylinder 2321 drives the movable material channel plate 2322 and the plurality of material ejecting plates to simultaneously move upwards, so that the material on the inclined material channel 23221 is lifted until the inclined material channel 23221 is aligned with the intermediate material channel 23104, and the material slides on the inclined material channel 23221 and the intermediate material channel 23104 and slides out of the material outlet 23103. Meanwhile, the ejector plate can eject and drop the materials which are not parallel to the ejector plate to the discharge opening 222, so that the materials are stirred.
So increase discharge gate 23103's height, reduce liftout cylinder 2321's stroke, realize promoting step by step of material, increase the area that liftout board and material contacted on horizontal simultaneously, the liftout scope increases, improves the probability of selecting the material parallel with the liftout board.
Referring to fig. 6 and 7, the rapid nail feeding mechanism 30 includes a material transfer box 31, a feeding pipe 32 and a discharging pipe 33 spaced apart from a top plate of the material transfer box 31, a material transfer block 34 slidably disposed in the material transfer box 31, a transfer cylinder 35 for driving the material transfer block 34 to move, and a material blocking cylinder 36.
The material transfer box 31 has a top plate 311 and a bottom plate 312.
A first through hole and a second through hole are formed in the top plate 311 of the material transfer box 31 at intervals, the feeding pipe 32 is communicated with the first through hole, and the discharging pipe 33 is communicated with the second through hole.
The middle part of the material transfer block 34 is provided with a third through hole 341, and when the material transfer block 34 moves, the third through hole 341 can be movably communicated with the first through hole or the second through hole.
The material transfer box 31 has a blowing channel formed in the bottom plate 312, a blowing outlet 3121 of the blowing channel is formed on the top surface of the bottom plate 312 and opposite to the second through hole, and a blowing inlet 3122 is formed on any other side surface of the bottom plate 312. The air blowing inlet 3122 is connected to an air supply unit.
A material blocking opening is formed in the side surface of the feeding pipe 32, the output end of the material blocking cylinder 36 is connected with a material blocking rod 361, and the material blocking rod 361 movably extends into the feeding pipe 32 through the material blocking opening to block materials.
The outlet pipe 33 is connected to a welding gun via a connecting hose.
The material continuously enters the material pipe 40 through the transition pipe 233, so that a plurality of materials are arranged in the material pipe 40 in an abutting manner end to end.
A controller is connected to the welding gun, the first material sensor 223, the second material sensor 234, the transfer cylinder 35, the material blocking cylinder 36, the material ejecting cylinder 2321 and an alarm.
The first material sensor 223 is used for sensing whether the material in the bin 22 is less than a predetermined value, and if so, the controller controls the alarm to give an alarm to remind an operator to replenish the bin 22 with the material.
The second material sensor 234 is used for sensing whether the material in the material pipe 40 reaches a predetermined value, which indicates that the material in the material pipe 40 is too much to contain more material, and the controller controls the material ejecting cylinder 2321 to suspend operation. Otherwise, the controller controls the material ejecting cylinder 2321 to work so as to supplement the material into the material pipeline 40.
The welding gun sends an operation signal to the controller every time the welding gun works, and the controller controls the blocking cylinder 36 to work once, namely, the blocking rod 361 is driven to retract and extend first, so as to discharge one material in the feeding pipe 32 to the material transfer box 31.
At the same time, the controller controls the transfer cylinder 35 to operate once, i.e., drives the material transfer block 34 to advance a distance toward the tapping pipe 33 and then to retract a distance, thereby transferring material from the feeding pipe 32 to the tapping pipe 33.
When the third through hole 341 of the material transfer block 34 is communicated with the second through hole and the blowing outlet 3121, the air supply unit blows air, and the material rapidly passes through the discharge pipe 33 and the connecting hose under the action of air pressure and enters the welding gun.
Compared with the prior art, the pin welding and feeding system for the boiler factory comprises a rack 10, a feeding assembly 20 and a rapid nail feeding mechanism 30 which are arranged on the rack 10, and a material pipeline 40 for connecting the feeding assembly 20 and the rapid nail feeding mechanism 30; the rapid nail feeding mechanism 30 is positioned below the feeding assembly 20; the feeding assembly 20 comprises a stock bin 22 and a nail selecting and feeding mechanism 23; one side of the bottom of the storage bin 22 is provided with a discharge opening 222, and the nail selecting and feeding mechanism 23 is arranged close to the discharge opening 222; the nail selecting and feeding mechanism 23 comprises a feeding support 231 and a multi-stage ejection mechanism 232 movably arranged on the feeding support 231. Therefore, the successful probability of material ejection can be improved, the working efficiency is improved, and quick material supplement is realized.
The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the scope of the present invention, and any modifications, equivalents or improvements that are within the spirit of the present invention are intended to be covered by the following claims.
Claims (7)
1. The utility model provides a boiler factory pin welding feeding system which characterized in that: the device comprises a rack, a feeding assembly and a quick nail feeding mechanism which are arranged on the rack, a material channel pipe for connecting the feeding assembly and the quick nail feeding mechanism, a connecting hose and a welding gun; the rapid nail feeding mechanism is positioned below the feeding assembly; the feeding assembly comprises a stock bin and a nail selecting and feeding mechanism; a discharge opening is formed in one side of the bottom of the storage bin, and the nail selecting and feeding mechanism is arranged close to the discharge opening; the nail selecting and feeding mechanism comprises a feeding support and a multi-stage ejection mechanism movably arranged on the feeding support; the connecting hose is connected with the quick nail feeding mechanism and the welding gun; the feeding support is provided with two side plates which are oppositely arranged and a middle plate which is connected with the bottoms of the two side plates, a plurality of partition plates are arranged between the two side plates at intervals above the middle plate, the heights of the plurality of partition plates which are arranged on the feeding support are gradually increased from one side close to the discharging opening to one side far away from the discharging opening, first gaps are formed between every two adjacent partition plates and between each partition plate and the middle plate, the top of one side plate is provided with a discharging opening, a transition pipe is arranged on the outer side of the discharging opening, and a second material sensor is arranged on each transition pipe; the multistage ejection mechanism comprises an ejection cylinder, a movable material channel plate connected with an output shaft of the ejection cylinder and a plurality of ejection plates which are sequentially connected, wherein the ejection plate closest to the movable material channel plate is connected with the movable material channel plate, the arrangement heights of the plurality of ejection plates are gradually reduced from one side close to the movable material channel plate to one side far away from the movable material channel plate, the ejection plates are movably positioned in the first gap, and the movable material channel plate is positioned on the outer side, far away from the storage bin, of the uppermost partition plate; the rapid nail feeding mechanism comprises a material transfer box, a feeding pipe and a discharging pipe which are arranged on a top plate of the material transfer box at intervals, a material transfer block which is positioned in the material transfer box in a sliding manner, a transfer cylinder and a material blocking cylinder which are used for driving the material transfer block to move; the material transfer box is provided with a top plate and a bottom plate, a first through hole and a second through hole are formed in the top plate of the material transfer box at intervals, the feeding pipe is communicated with the first through hole, the discharging pipe is communicated with the second through hole, a third through hole is formed in the middle of the material transfer block and is movably communicated with the first through hole or the second through hole, an air blowing channel is formed in the bottom plate of the material transfer box, and an air blowing outlet of the air blowing channel is formed in the top surface of the bottom plate and is opposite to the second through hole; the side surface of the feeding pipe is provided with a material blocking port, the output end of the material blocking cylinder is connected with a material blocking rod, and the material blocking rod movably extends into the feeding pipe through the material blocking port; and a controller is connected with the welding gun, the second material sensor, the transfer cylinder, the material blocking cylinder, the material ejecting cylinder and an alarm.
2. The boiler plant pin weld feed system of claim 1, wherein: the number of the partition plates is 3, and the partition plates are respectively a first partition plate, a second partition plate and a third partition plate; the number of the ejector plates is 3, and the ejector plates are respectively a first ejector plate, a second ejector plate and a third ejector plate, and the first ejector plate and the movable material channel plate, the first ejector plate and the second ejector plate and the third ejector plate are connected through a first connecting block; the top of activity material guidance tape board has the slope material and says that the height of slope material is from keeping away from the one end of discharge gate to the one end of orientation discharge gate reduces gradually.
3. The boiler plant pin weld feed system of claim 2, wherein: the top surfaces of the first partition plate, the second partition plate and the third partition plate are all inclined surfaces, and the heights of the inclined surfaces are gradually reduced from one side close to the discharge opening to one side far away from the discharge opening.
4. The boiler plant pin weld feed system of claim 2, wherein: the top of one side of the movable material channel plate, which is far away from the ejector plate, is provided with a baffle, and the baffle protrudes upwards from the inclined material channel.
5. The boiler plant pin weld feed system of claim 1, wherein: and one side of the ejector plate, far away from the movable material channel plate, of the ejector plate, is provided with a sliding block, one side of the intermediate plate, facing the ejector cylinder, is provided with a guide rail, and the sliding block is in sliding connection with the guide rail.
6. The boiler plant pin weld feed system of claim 1, wherein: the bottom of feed bin has the slope, and the ejection of compact opening is located the bottom on slope, and the feed bin is provided with first material inductor in ejection of compact opening's top.
7. The boiler plant pin weld feed system of claim 1, wherein: one side of the discharge port, which is far away from the transition pipe, is obliquely provided with an intermediate material channel communicated with the discharge port; the end of the middle material channel close to the discharge hole is flush with the discharge hole, and the end far away from the discharge hole is higher than the discharge hole.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202011369827.1A CN112372190B (en) | 2020-11-30 | 2020-11-30 | Boiler factory pin welding feeding system |
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202011369827.1A CN112372190B (en) | 2020-11-30 | 2020-11-30 | Boiler factory pin welding feeding system |
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| CN112372190A true CN112372190A (en) | 2021-02-19 |
| CN112372190B CN112372190B (en) | 2022-06-14 |
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| CN202011369827.1A Active CN112372190B (en) | 2020-11-30 | 2020-11-30 | Boiler factory pin welding feeding system |
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Denomination of invention: Boiler Factory Pin Welding and Feeding System Granted publication date: 20220614 Pledgee: Zhejiang Jiashan rural commercial bank Limited by Share Ltd. science and technology sub branch Pledgor: Zhejiang Chuangli Welding Technology Co.,Ltd. Registration number: Y2024330000348 |