CN220617568U - Stacked fin stacking machine - Google Patents

Abstract

The utility model discloses a stacking machine for stacked fins, which comprises a pull plate assembly, a first fixing plate, an upper pull plate, a lower pull plate and a second fixing plate, wherein the first fixing plate, the upper pull plate, the lower pull plate and the second fixing plate are sequentially arranged on the support from top to bottom, the first fixing plate is connected with the upper pull plate through a first air cylinder, the lower pull plate is connected with the second fixing plate through a second air cylinder, the stacking machine comprises a conveyor belt assembly, the conveyor belt assembly is connected with an operation table assembly, the operation table assembly is arranged below the pull plate assembly, the pull plate assembly is connected with a push plate assembly, and a supporting plate assembly is arranged below the pull plate assembly. According to the utility model, the structure is not laminated, fins are collected and stacked through the pull plate, then the stacked and tidied fin sample bands are stored in a concentrated manner by workers, each step of action can not influence other actions, a whole set of actions are circularly and orderly carried out, and the fin stacking and collecting efficiency is greatly improved.

Description

Stacked fin stacking machine

Technical Field

The utility model relates to the technical field of mechanical automation, in particular to a stacking type fin stacking machine.

Background

The fin stacker is equipment for replacing manually transferring processed fins in the manufacturing process of heat exchange fins, and is mainly used for conveying and collecting formed sample strips in the automobile radiator industry. The performance of the stacking machine has an important influence on realizing the mass fin production pipelining.

At present, most of practical fin stacking machines are single-layer simple stacking machines, namely, after a conveyor belt receives sample belts, the sample belts are immediately pushed out of a working table surface to be folded and unfolded by workers, and the workers need to arrange, stack and centrally store a plurality of sample belts in a matching way with the conveying time of the stacking machine. Along with the improvement of fin transmission speed, simple single-layer fin stacking machine collection efficiency lags behind, once the transmission speed of fin stacking machine is accelerated, ordinary workman can't keep up the work rhythm of machine, influences the work progress on the contrary. Therefore, research on realizing the multilayer stacked fin stacking machine is necessary for collecting the fins, and the production efficiency is further improved.

Disclosure of Invention

The utility model provides a stacked fin stacking machine, which aims to solve the problem that the work progress is affected by incapability of keeping up with the work rhythm of a machine by a common worker once the collection efficiency of the stacking machine is lagged and the transmission rate of the fin stacking machine is quickened in the prior art.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

the utility model provides a range upon range of fin stacking machine, includes the pull plate subassembly, the pull plate subassembly includes the support, still includes first fixed plate, last pull plate, lower pull plate and the second fixed plate that top-down set gradually on the support, link to each other through first cylinder between first fixed plate and the last pull plate, link to each other through the second cylinder between lower pull plate and the second fixed plate.

Further, the support includes fore-stock and back support, first fixed plate includes preceding first fixed plate and back first fixed plate, go up the pull board and go up the pull board including preceding pull board and back, lower pull board includes preceding lower pull board and back lower pull board, the second fixed plate includes preceding second fixed plate and back second fixed plate, first cylinder includes preceding first cylinder and back first cylinder, the second cylinder includes preceding second cylinder and back second cylinder.

Further, the stacking machine comprises a conveying belt assembly, the conveying belt assembly is connected with an operation table assembly, the operation table assembly is arranged below the drawing plate assembly, the drawing plate assembly is connected with a push plate assembly, and a supporting plate assembly is arranged below the drawing plate assembly.

Further, the layer board subassembly includes the support movable plate, the support movable plate is connected with rotatory lead screw through rotatory lead screw fixing base, the support movable plate is connected with the guide post through the linear guide fixing base, the guide post is connected with the bearing bedplate through linear bearing, be equipped with a plurality of lower pillars on the bearing bedplate.

Further, the support plate assembly further comprises a second servo motor and a third servo motor, the second servo motor is connected with a third toothed belt wheel, the third toothed belt wheel is arranged on the rotary screw rod, the second servo motor is fixed on the bearing seat plate through a second motor flange vertical seat and a second motor flange plate, the third servo motor is connected with a second speed reducer, the second speed reducer is connected with a first coupler, the first coupler is connected with a first ball screw, and a screw fixing plate is arranged on the first ball screw.

Further, the push plate assembly comprises a lower push plate and a triaxial cylinder, wherein the triaxial cylinder is connected with the lower push plate through a third inner hexagonal cylinder head, and the triaxial cylinder is connected with a lower bracket. The three-axis air cylinders are two and are respectively arranged at the two ends of the same side of the lower pushing plate.

Further, the conveyer belt subassembly includes conveyer belt and first servo motor, the both sides of conveyer belt are equipped with the guide rail board, first servo motor is connected with first profile of tooth band pulley through first reduction gear, first profile of tooth band pulley is connected with second profile of tooth band pulley through the gear area, second profile of tooth band pulley pass through the main drive shaft with the conveyer belt links to each other, first servo motor passes through the motor fixed plate to be fixed in the one end of conveyer belt.

Further, the operation panel subassembly includes regulator cubicle and conveyer belt stand, the top of regulator cubicle is equipped with preceding bed surface and back bed surface, be equipped with the electrical panel in the regulator cubicle, the regulator cubicle is located on the sales counter frame, the sales counter frame with the one end of conveyer belt stand links to each other, the other end of conveyer belt stand is connected with the connecting plate, be equipped with the stabilizer plate on the conveyer belt stand.

Further, the stacking machine further comprises an operation box assembly, the operation box assembly comprises an operation box and an aluminum pipe, the operation box is connected with one end of the aluminum pipe through a connector, and the other end of the aluminum pipe is connected with a vertical wall base.

Further, the stacking machine further comprises a protective cover, the protective cover comprises a first protective cover and a second protective cover, and the first protective cover and the second protective cover are respectively arranged on the front side and the rear side of the drawing plate assembly.

Therefore, the utility model has the following beneficial effects:

the fin that this device was transmitted by the conveyer belt subassembly is first to the first layer of pull plate subassembly, on the pull plate promptly, when the fin on the pull plate was accumulated to a certain quantity on the last pull plate, the last pull plate was opened, the fin that accumulated on the last pull plate falls to the second layer of pull plate subassembly promptly on the pull plate down, afterwards go up the pull plate and repeat the action above until the fin on the pull plate down is accumulated to a certain quantity or layer number back pull plate and is opened, the fin that accumulates on the pull plate down falls to the support plate of layer board subassembly (third layer) below, the support plate is moved down to be leveled with the bed surface of operation panel subassembly, push plate assembly's push plate pushes away the fin on the support plate to the bed surface of operation panel, then by the workman concentrated deposit the fin sample area that stacks like this and accomplish, every step action can not cause the influence to other actions, a whole set of action circulation is orderly carries out, the efficiency that the fin is stacked and collected greatly.

Drawings

FIG. 1 is a schematic view of the overall structure of the stacker of the present utility model;

FIG. 2 is a front view of the stacker of the present utility model;

FIG. 3 is a front view of the drawer plate assembly of the present utility model;

FIG. 4 is a schematic view of the overall structure of a view angle of the drawer plate assembly of the present utility model;

FIG. 5 is a schematic view of another view of the overall structure of the drawer plate assembly of the present utility model;

FIG. 6 is an enlarged view of a portion of the drawer plate assembly of the present utility model;

FIG. 7 is a schematic view of the overall construction of the conveyor belt assembly of the present utility model;

FIG. 8 is a top view of the conveyor belt assembly of the present utility model;

FIG. 9 is a front view of the pallet assembly of the present utility model;

FIG. 10 is a schematic view of the overall construction of the pallet assembly of the present utility model;

FIG. 11 is a schematic view of the overall structure of the push plate assembly of the present utility model from one perspective;

figure 12 is a schematic view of another view of the overall structure of the push plate assembly of the present utility model;

FIG. 13 is a front view of the console assembly of the present utility model;

FIG. 14 is a schematic view of the overall construction of the console assembly of the present utility model;

fig. 15 is a front view of the operator's compartment assembly of the present utility model.

In the figure: 1. a conveyor belt assembly; 2. an operator station assembly; 3. a drawer plate assembly; 4. a push plate assembly; 5. an operator box assembly; 6. a pallet assembly; 7. a first shield; 8. a second shield; 11. a first hexagon socket cap head; 12. a driven shaft fixing plate; 13. a second hexagon socket cap head; 14. a conveyor belt; 15. a first rail plate; 16. a second rail plate; 17. a first toothed pulley; 18. a second toothed pulley; 19. an air injection fixing plate; 110. a first servo motor; 111. a main drive shaft; 112. a motor fixing plate; 113. a driving shaft fixing plate; 114. a first decelerator; 115. a driven shaft; 116. a driven shaft roller; 21. a baseboard; 22. a stabilizing plate; 23. a connecting plate; 24. a conveyor belt upright; 25. an electrical cabinet door; 26. a counter frame; 27. an electrical cabinet; 28. an electrical board; 29. a front bed surface; 210. a rear bed surface; 31. a first fixing plate; 32. an upper drawing plate; 33. a lower drawing plate; 34. a second fixing plate; 35. a first cylinder; 36. a second cylinder; 37. a tank chain; 38. a front bracket; 39. a rear bracket; 310. a first upper plate; 311. a first intermediate plate; 312. a second upper plate; 313. a second intermediate plate; 314. a first lower plate; 301. a front first fixing plate; 302. a rear first fixing plate; 305. a front lower drawing plate; 306. a rear lower drawer plate; 307. a front second fixing plate; 308. a rear second fixing plate; 309. a front first cylinder; 315. a rear first cylinder; 316. a front second cylinder; 317. a rear second cylinder; 318. a tape feeding supporting plate; 319. a first linear guide rail; 320. a fourth servo motor; 321. a second linear guide rail; 322. a guide arrow; 323. a baffle; 324. a second coupling; 325. a third decelerator; 326. the second motor base; 327. a screw support; 328. a ninth hexagon socket cap head; 329. a second ball screw; 330. a second lead screw nut; 331. a nut seat is arranged; 332. a sensor holder; 333. a tenth hexagon socket cap head; 334. a photoelectric sensor; 335. heightening the pad; 41. a third hexagon socket cap head; 42. a triaxial cylinder; 43. a lower push plate; 44. a lower bracket; 45. a fourth hexagon socket cap head; 51. an operation box; 52. a connector; 53. an aluminum pipe; 54. a vertical wall base; 61. a linear bearing; 62. a bearing seat plate; 63. rotating the screw rod fixing seat; 64. rotating a screw rod nut; 65. a third toothed pulley; 66. a motor flange vertical seat; 67. a motor flange; 68. a linear guide rail fixing seat; 69. a fifth hexagon socket cap head; 610. a supporting plate; 611. a guide post; 612. a second servo motor; 613. rotating the lead screw; 614. a screw fixing plate; 615. a first motor base; 616. a first lead screw nut; 617. a sensor fixing plate; 618. a sixth hexagon socket cap head; 619. a seventh hexagon socket cap head; 620. a lower support column; 621. a second decelerator; 622. eighth hexagon socket cap head; 623. a first coupling; 624. a first ball screw; 625. and a third servo motor.

Detailed Description

Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative and intended to explain the present utility model and should not be construed as limiting the utility model.

In the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

As shown in fig. 1 and 2, a stacked fin stacker includes a drawing plate assembly 3. As shown in fig. 3, 4 and 5, the drawing plate assembly 3 includes a bracket, and further includes a first fixing plate 31, an upper drawing plate 32, a lower drawing plate 33 and a second fixing plate 34 sequentially disposed on the bracket from top to bottom, wherein the first fixing plate 31 and the upper drawing plate 32 are connected through a first air cylinder 35, and the lower drawing plate 33 and the second fixing plate 34 are connected through a second air cylinder 36.

The first and second fixing plates 31 and 36 are for fixedly mounting the first and second cylinders 35 and 36.

The stacking machine further comprises a conveyor belt assembly 1, the conveyor belt assembly 1 is connected with an operation table assembly 2, the operation table assembly 2 is arranged below the drawing plate assembly 3, the drawing plate assembly 3 is connected with a push plate assembly 4, and a supporting plate assembly 6 is arranged below the drawing plate assembly 3.

The drawing plate assembly 3 of the device is of a laminated structure, fins conveyed by the conveying belt assembly 1 are firstly conveyed to the first layer of the drawing plate assembly 3, namely the upper drawing plate 32, when the fins on the upper drawing plate 32 are accumulated to a certain number, the upper drawing plate 32 is opened, the fins accumulated on the upper drawing plate 32 fall to the second layer of the drawing plate assembly 3, namely the lower drawing plate 33, then the upper drawing plate 32 repeats the above action until the fins on the lower drawing plate 33 are accumulated to a certain number or a certain number of layers, the lower drawing plate 306 is opened, the fins accumulated on the lower drawing plate 33 fall to the supporting plate 610 of the supporting plate assembly 6 (the third layer) below, the supporting plate 610 moves downwards to be flat with the surface of the operating table assembly 2, the fins on the supporting plate 610 are pushed to the surface of the operating table by the lower pushing plate 43 of the pushing plate assembly 4, the stacked fin sample bands are stored intensively by workers, each step does not affect other bed lifting actions, the bed lifting efficiency is improved, the bed stacking and the circulating fins are amplified, and the collecting fins are amplified.

The bracket, the first fixing plate 31, the upper drawing plate 32, the lower drawing plate 33 and the second fixing plate 34 are all two, specifically, as shown in fig. 4 and 5, the bracket comprises a front bracket 38 and a rear bracket 39, the first fixing plate 31 comprises a front first fixing plate 301 and a rear first fixing plate 302, the upper drawing plate 32 comprises a front upper drawing plate and a rear upper drawing plate, the lower drawing plate 33 comprises a front lower drawing plate 305 and a rear lower drawing plate 306, the second fixing plate 34 comprises a front second fixing plate 307 and a rear second fixing plate 308, the first cylinder 35 comprises a front first cylinder 309 and a rear first cylinder 315, and the second cylinder 36 comprises a front second cylinder 316 and a rear second cylinder 317.

In this embodiment, as shown in fig. 4, a front first fixing plate 301, a front upper drawer plate (hidden by the front first fixing plate 301, not shown), a front lower drawer plate 305, and a front second fixing plate 307 are all provided on the front bracket 38, a front first cylinder 309 is provided on the front first fixing plate 301, a front second cylinder 316 is provided on the front second fixing plate 307, and the front first cylinder 309 is connected to the front upper drawer plate, and the front second cylinder 316 is connected to the front lower drawer plate 305.

In this embodiment, as shown in fig. 5, the rear first fixing plate 302, the rear upper drawer plate (blocked by the rear first fixing plate 302, not shown), the rear lower drawer plate 306, and the rear second fixing plate 308 are all disposed on the rear bracket 39, the rear first cylinder 315 is disposed on the rear first fixing plate 302, the rear second cylinder 317 is disposed on the rear second fixing plate 308, and the rear first cylinder 315 is connected to the rear upper drawer plate, and the rear second cylinder 317 is connected to the rear lower drawer plate 306. A tank chain 37 is also connected to the rear second fixing plate 308.

Gaps are reserved between the front first fixing plate 301 and the rear first fixing plate 302 and between the front second fixing plate 307 and the rear second fixing plate 308, and a certain distance is reserved between the front first fixing plate 301 and the rear first fixing plate 302, so that the fins can fall down from the middle.

The front bracket 38 and the rear bracket 39 are arranged back to back and are opposite to each other, the front upper drawing plate and the rear upper drawing plate are located at the same height, the front lower drawing plate 305 and the rear lower drawing plate 306 are located at the same height, the front upper drawing plate and the rear upper drawing plate can be opened and closed (opened, that is, the front upper drawing plate and the rear upper drawing plate are moved to two sides and separated, closed, that is, the front lower drawing plate 305 and the rear lower drawing plate 306 are moved to the middle and closed) under the driving of the air cylinder.

The connection part of the drawing plate assembly 3 and the conveyor belt assembly 1 is provided with a belt feeding supporting plate 318, the belt feeding supporting plate 318 is fixed on the front bracket 38 and the rear bracket 39, a gap is reserved between the front bracket 38 and the rear bracket 39, fins enter the gap between the front bracket 38 and the rear bracket 39 through the belt feeding supporting plate 318 and then fall onto the upper drawing plate 32 of the drawing plate assembly 3, and at the moment, the front upper drawing plate and the rear upper drawing plate are closed together.

The pull plate assembly 3 further includes a driving shaft fixing plate 310, a first middle connecting plate 311, a second upper connecting plate 312, a second middle connecting plate 313, and a first lower connecting plate 314, where the driving shaft fixing plate 310, the first middle connecting plate 311, the second upper connecting plate 312, the second middle connecting plate 313, and the first lower connecting plate 314 are all disposed in the middle of the front bracket 38 and the rear bracket 39, the driving shaft fixing plate 310, the first middle connecting plate 311, and the first lower connecting plate 314 are sequentially disposed on the front bracket 38 from top to bottom, a certain gap is left between the driving shaft fixing plate 310 and the first middle connecting plate 311, between the first middle connecting plate 311 and the first lower connecting plate 314, the second upper connecting plate 312 and the second middle connecting plate 313 are sequentially disposed on the rear bracket 39 from top to bottom, and a certain gap is left between the second upper connecting plate 312 and the second middle connecting plate 313, and the gap corresponds to the gap left between the driving shaft fixing plate 310 and the first middle connecting plate 311. The front upper drawing plate and the rear upper drawing plate pass through the gap between the driving shaft fixing plate 310 and the first middle connecting plate 311, and the gap between the second upper connecting plate 312 and the second middle connecting plate 313 to realize closing and opening under the action of the air cylinder.

The drawing plate assembly 3 further comprises a second linear guide rail 321, the second linear guide rail 321 is located at the uppermost part of the bracket, a guide arrow 322 and a baffle 323 are arranged on the second linear guide rail 321, and a first linear guide rail 319 is arranged at the bottom end of the bracket. As shown in fig. 6, the drawing board assembly 3 further includes a fourth servo motor 320, the fourth servo motor 320 is connected with a third decelerator 325, the third decelerator 325 is connected with one end of a second ball screw 329 through a second coupling 324, a second motor seat 326 is disposed at the connection between the third decelerator 325 and the second coupling 324, a screw support 327 is disposed at the connection between the second coupling 324 and the second ball screw 329, a heightening pad 335 is disposed below the screw support 327, and the heightening pad 335 is connected with the screw support 327 through a ninth hexagon socket head 328. The other end of the second ball screw 329 is connected with an upper screw seat 331, the upper screw seat 331 is connected with the other end of the second ball screw 329 through a second screw nut 330, a sensor bracket 332 is arranged on the side face of the upper screw seat 331, the sensor bracket 332 is used for installing and fixing a photoelectric sensor 334, and the photoelectric sensor 334 is fixed on the sensor bracket 332 through a tenth hexagon socket head 333.

The pallet assembly 6, as shown in fig. 9 and 10, comprises a supporting plate 610, wherein the supporting plate 610 is connected with a rotating screw 613 through a rotating screw fixing seat 63, the supporting plate 610 is connected with two guide posts 611 through a linear guide fixing seat 68, the guide posts 611 are connected with a bearing seat plate 62 through linear bearings 61, and a plurality of lower support posts 620 are arranged on the bearing seat plate 62. The components of the pallet assembly 6 other than the pallet 610 are disposed within the operator's station assembly's electrical cabinet 27, and the lower support column 620 is connected to the rear deck 210 within the electrical cabinet 27.

The pallet assembly 6 further comprises a second servo motor 612 and a third servo motor 625, the second servo motor 612 is connected with a third toothed belt wheel 65, the third toothed belt wheel 65 is arranged on the rotary screw 613, the second servo motor 612 is fixed on the bearing seat plate 62 through a motor flange vertical seat 66 and a motor flange 67, the third servo motor 625 is connected with a second reducer 621, the second reducer 621 is connected with a first coupler 623, the first coupler 623 is connected with a first ball screw 624, the second reducer 621 is provided with a first motor seat 615, and a screw fixing plate 614 is arranged on the first ball screw 624. The servo motor in the pallet assembly 6 is used to drive the pallet 610 up and down.

The pallet assembly 6 further comprises a rotating screw nut 64, a fifth inner hexagonal cylinder head 69, a first screw nut 616, a sensor fixing plate 617, a sixth inner hexagonal cylinder head 618, a seventh inner hexagonal cylinder head 619, an eighth inner hexagonal cylinder head 622, the rotating screw nut 64 being located directly below the rotating screw fixing seat 63, the fifth inner hexagonal cylinder head 69 being used for fixing the linear guide fixing seat 68 on the moving plate, the first screw nut 616 being used for fixing the screw fixing plate 614, the sensor fixing plate 617 being fixed on the linear bearing 61 through the sixth inner hexagonal cylinder head 618, the seventh inner hexagonal cylinder head 619 being mounted at one end of the lower post 620, the eighth inner hexagonal cylinder head 622 connecting the second speed reducer 621 and the first motor seat 615.

The push plate assembly 4 comprises a lower push plate 43 and a triaxial cylinder 42, wherein the triaxial cylinder 42 is connected with the lower push plate 43 through a third hexagonal cylinder head 41, and the triaxial cylinder 42 is connected with a lower bracket 44. In this embodiment, as shown in fig. 11 and 12, there are two triaxial cylinders 42 provided at both ends of the same side of the lower push plate 43, respectively. The triaxial cylinder 42 is fixedly connected with the rear bed surface 210 of the console through a fourth hexagon socket head cap 45. The triaxial cylinder 42 drives the lower push plate 43 to move back and forth, so that the fins on the supporting plate 610 are pushed onto the front bed surface 29 of the operation box 2.

The conveyor belt assembly 1 is shown in fig. 7 and 8, and comprises a conveyor belt 14 and a first servo motor 110, wherein guide rail plates are arranged on two sides of the conveyor belt 14, each guide rail plate comprises a first guide rail plate 15 and a second guide rail plate 16, the first guide rail plates 15 and the second guide rail plates 16 are respectively positioned on two sides of the conveyor belt 14, the first servo motor 110 is connected with a first toothed belt wheel 17 through a first speed reducer 114, the first toothed belt wheel 17 is connected with a second toothed belt wheel 18 through a gear belt, the second toothed belt wheel 18 is connected with the conveyor belt 14 through a main transmission shaft 111, and the first servo motor 110 is fixed at one end of the conveyor belt 14 through a motor fixing plate 112. The first servo motor 110 drives the conveyor 14 in motion.

The conveyor belt assembly 1 further comprises a first inner hexagonal cylindrical head 11, a driven shaft fixing plate 12, a second inner hexagonal cylindrical head 13, an air injection fixing plate 19, a driving shaft fixing plate 113, a driven shaft 115 and a driven shaft roller 116, wherein the driven shaft 115 and the driven shaft roller 116 are arranged at one end, far away from the drawing plate assembly 3, of the conveyor belt 14, the driven shaft roller 116 is connected with the conveyor belt 14, the conveyor belt 14 is driven to move in an auxiliary mode, the driven shaft fixing plate 12 is connected with the driven shaft 115 through the first inner hexagonal cylindrical head 11 and used for fixing the driven shaft, the second inner hexagonal cylindrical head 13 is used for fixing the driven shaft fixing plate 12, and the driving shaft fixing plate 113 is connected with the first speed reducer 114.

As shown in fig. 13 and 14, the console assembly 2 includes a cabinet 27 and a conveyor stand 24, a front bed surface 29 and a rear bed surface 210 are disposed above the cabinet 27, an electric board 28 is disposed in the cabinet 27, the cabinet 27 is disposed on a counter frame 26, the counter frame 26 is connected to one end of the conveyor stand 24, the other end of the conveyor stand 24 is connected to a connecting plate 23, and a stabilizing plate 22 is disposed on the conveyor stand 24. A floor board 21 is provided below the counter frame 26 where it contacts the ground, and electric cabinet doors 25 are provided on the front and rear sides of the front ghost.

The connecting plates 23 and the stabilizing plates 22 are used for connection with the conveyor belt assembly, two each of the connecting plates 23 and the stabilizing plates 22 being fixedly connected with the first rail plate 15 and the second rail plate 16 in the manner shown in fig. 1.

As shown in fig. 14, in the console assembly 2, a gap is formed between the front bed surface 29 and the rear bed surface 210, the size of the gap is equal to that of the supporting plate 610 in the supporting plate assembly 6, and the supporting plate 610 descends to the same height as the front bed surface 29 after receiving the fins, and just fills the gap between the front bed surface 29 and the rear bed surface 210.

As shown in fig. 15, the stacker further includes an operation box assembly 5, the operation box assembly 5 includes an operation box 51 and an aluminum pipe 53, one ends of the operation box 51 and the aluminum pipe 53 are connected by a connector 52, and the other end of the aluminum pipe 53 is connected with a vertical wall base 54. The operation box 51 is fixed to the side of the electric cabinet 27 through a vertical wall mount 54 and an aluminum pipe 53.

As shown in fig. 1, the stacking machine further includes a protective cover, which includes a first protective cover 7 and a second protective cover 8, and the first protective cover 7 and the second protective cover 8 are respectively disposed on the front and rear sides of the drawing board assembly 3.

When the device works, after the heat dissipation belt is cut off by a fin machine, the heat dissipation belt enters the conveyor belt assembly 1 and is conveyed to a channel for bridging, namely a belt feeding supporting plate 318, through the belt feeding supporting plate 318, and the fin enters the laminated structure, namely the drawing plate assembly 3 and the supporting plate assembly 6. The drawer plate assembly 3 is mainly divided into two layers from top to bottom, wherein the first layer is an upper drawer plate 32 (including a front upper drawer plate and a rear upper drawer plate), and the front upper drawer plate and the rear upper drawer plate on two sides of the first layer are folded before the fins pass through the strip inlet supporting plate 318 under the driving of the first air cylinder 35. The second layer is a lower drawing plate (including a front lower drawing plate 305 and a rear lower drawing plate 306), the lower drawing plate is used for arranging the stacking and laying-out belt, and is driven by a second air cylinder 36, and before the fins fall down, the folding of the front lower drawing plate 305 and the rear lower drawing plate 306 on two sides of the second layer is completed. The fins transferred from the conveyor 14 are first fed onto the upper drawing plate 32 of the first layer through the feed belt supporting plate 318, when the upper drawing plate 32 of the first layer is accumulated to a certain amount (or after a fixed time), the first cylinder 35 is operated to separate the front upper drawing plate and the rear upper drawing plate so that the fins fall onto the lower drawing plate of the second layer, the above operation is repeated until the fins on the lower drawing plate are accumulated to a certain amount or layer number, the second cylinder 36 is operated to open the front lower drawing plate 305 and the rear lower drawing plate 306, the accumulated sorted fins on the lower drawing plate fall onto the lower third layer, namely, the supporting plate 610 of the supporting plate assembly 6, after the supporting plate 610 receives the fallen fins, the supporting plate moves down to be leveled with the bed surface of the operation table assembly 2, the fins on the supporting plate 610 are pushed onto the bed surface of the operation table by the lower pushing plate 43 of the pushing plate assembly 4, and then the finished fin strips thus stacked and finished by workers are concentrated. Each step of action can not influence other actions, and a whole set of action is circularly carried out, so that the fin stacking and collecting efficiency is greatly improved.

The utility model adopts a multi-layer design, and the machine is used for carrying out conveying, collecting, arranging and stacking, so that workers only need to intensively store batches of fins after stacking, the labor burden is reduced, and the production efficiency is greatly improved.

In the description of the present specification, a description referring to terms "one embodiment," "some embodiments," "examples," "specific examples," or "some examples," etc., means 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 present utility model. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

It will be readily understood by those skilled in the art that the present utility model, including any combination of parts described in the summary and detailed description of the utility model above and shown in the drawings, is limited in scope and does not constitute a complete description of the various aspects of these combinations for the sake of brevity. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Although embodiments of the present utility model have been shown and described above, it will be understood that the above embodiments are illustrative and not to be construed as limiting the utility model, and that variations, modifications, alternatives, and variations may be made in the above embodiments by those skilled in the art without departing from the spirit and principles of the utility model. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (10)

1. The utility model provides a range upon range of fin stacking machine, its characterized in that, includes the pull board subassembly, the pull board subassembly includes the support, still includes the support top-down sets gradually first fixed plate, go up the pull board, lower pull board and second fixed plate, link to each other through first cylinder between first fixed plate and the last pull board, link to each other through the second cylinder between lower pull board and the second fixed plate.

2. The stacked fin stacker of claim 1, wherein said brackets comprise front and rear brackets, said first fixed plates comprise front and rear first fixed plates, said upper drawer comprises front and rear upper drawer plates, said lower drawer comprises front and rear lower drawer plates, said second fixed plates comprise front and rear second fixed plates, said first cylinder comprises front and rear first cylinders, and said second cylinder comprises front and rear second cylinders.

3. The stacked fin stacker of claim 1, further comprising a conveyor belt assembly connected with an operating table assembly, the conveyor belt assembly connected with the drawer plate assembly, the operating table assembly disposed below the drawer plate assembly, a pallet assembly disposed between the drawer plate assembly and the operating table assembly, and a push plate assembly connected to the drawer plate assembly.

4. A stacked fin stacker as claimed in claim 3 wherein said pallet assembly comprises a pallet plate connected with a rotating screw by a rotating screw holder, said pallet plate connected with a guide post by a linear guide holder, said guide post connected with a bearing plate by a linear bearing, said bearing plate being provided with a plurality of lower struts.

5. The stacked fin stacker of claim 4, wherein said pallet assembly further comprises a second servomotor and a third servomotor, said second servomotor is connected with a third toothed pulley, said third toothed pulley is disposed on said rotary screw, said second servomotor is fixed on said bearing plate via a motor flange mount and a motor flange plate, said third servomotor is connected with a second reducer, said second reducer is connected with a first coupling, said first coupling is connected with a first ball screw, and said first ball screw is provided with a screw fixing plate.

6. A stacked fin stacker according to claim 3, wherein said push plate assembly comprises a lower push plate and a triaxial cylinder connected to said lower push plate by a third hexagonal socket head cap, said triaxial cylinder being connected to a lower bracket.

7. A stacked fin stacker according to claim 3, wherein said conveyor belt assembly comprises a conveyor belt and a first servomotor, guide rail plates are provided on both sides of said conveyor belt, said first servomotor is connected with a first toothed belt wheel via a first reduction gear, said first toothed belt wheel is connected with a second toothed belt wheel, said second toothed belt wheel is connected with said conveyor belt via a main drive shaft, and said first servomotor is fixed to one end of said conveyor belt via a motor fixing plate.

8. A stacked fin stacker according to claim 3, wherein said console assembly comprises an electric cabinet and a conveyor stand, a front bed surface and a rear bed surface are provided above said electric cabinet, an electric plate is provided in said electric cabinet, said electric cabinet is provided on a counter frame, said counter frame is connected to one end of said conveyor stand, the other end of said conveyor stand is connected to a connecting plate, and a stabilizer plate is provided on said conveyor stand.

9. The stacked fin stacker of any one of claims 1 to 8, further comprising an operation box assembly including an operation box and an aluminum pipe, one ends of the operation box and the aluminum pipe being connected by a connector, and the other end of the aluminum pipe being connected with a vertical wall mount.

10. The stacked fin stacker of claim 1, further comprising a shield including a first shield and a second shield, the first shield and the second shield being disposed on front and rear sides of the drawer plate assembly, respectively.