A lead ingot stacking device
The design of the lead ingot stacking device solves the problems of large space occupation and low automation of traditional lead ingot stacking equipment, realizes the turning and staggered placement of lead ingots, and improves the efficiency and automation of lead ingot stacking.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- ZHEJIANG RUIQI TECH CO LTD
- Filing Date
- 2025-07-18
- Publication Date
- 2026-07-14
AI Technical Summary
In the lead ingot processing process, traditional palletizing equipment occupies a large space and has a low degree of automation. Furthermore, the lead ingots need to be frequently reoriented during the palletizing process, which makes the disposal process cumbersome.
A lead ingot stacking device was designed, comprising a stacking plate, a sealing component, a corner component, and a lifting component. The sealing component controls the opening and closing of the feeding chute, the corner component adjusts the direction of the lead ingots, and the lifting component realizes the stacking of lead ingots, thereby achieving the staggered placement of lead ingots by turning.
It improves the automation level of lead ingot stacking, reduces equipment space occupation, simplifies the lead ingot discharge process, and improves stacking efficiency.
Smart Images

Figure CN224492917U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the technical field of lead ingot processing, and in particular to a lead ingot stacking device. Background Technology
[0002] Lead is one of the earliest metals refined by humans. It is the softest heavy metal and one of the densest metals. Lead has good ductility and is easily alloyed with other metals. Lead alloys are widely used in the manufacture of plates, lead pipes, and lead plates for lead-acid batteries. The processing of lead ingots involves melting, casting, cooling and shaping, unloading and conveying, stacking, and packaging. During stacking, a gripping mechanism is used to grab multiple lead ingots that have been demolded and are being conveyed side-by-side onto a platform for stacking. Traditional stacking methods are lengthy, require numerous pieces of equipment, occupy a large space, have low automation, and low stacking efficiency. Furthermore, the stacking process often requires frequent changes in the orientation of the lead ingots for staggered placement, which can make the process cumbersome. Utility Model Content
[0003] The present invention aims to overcome the shortcomings of existing technologies in which lead ingots are not easily turned during the placement process, and provides a lead ingot stacking device that can turn lead ingots and then place them in a staggered manner.
[0004] To achieve the above objectives, the present invention adopts the following technical solution:
[0005] A lead ingot stacking device, comprising:
[0006] A palletizing plate, wherein the palletizing plate is provided with a plurality of material feeding grooves;
[0007] A sealing assembly, wherein the sealing assembly is mounted on a palletizing plate and corresponds to the feeding chute;
[0008] A corner assembly, wherein the corner assembly is connected to a palletizing plate;
[0009] A lifting assembly, which is connected to a corner assembly.
[0010] Lead ingots are placed on a palletizing plate, corresponding to the feeding chute. During placement, a sealing component can block the feeding chute. After placement, the feeding chute is opened by the sealing component to allow the lead ingots to be fed. The lead ingots are then transported to the palletizing plate via an external conveyor belt and other conveying mechanisms. During feeding, the direction of the palletizing plate can be changed by a corner component, allowing the lead ingots to be staggered. Simultaneously, a lifting component can support the palletizing plate and lift it, thus achieving the stacking of lead ingots and enabling them to be rotated and staggered.
[0011] Preferably, a plurality of feeding troughs are evenly distributed at one end of the palletizing plate, and partition plates are installed on both sides of the feeding troughs. A baffle is installed on the palletizing plate, and the end of the partition plate furthest from the end of the palletizing plate is connected to the partition plate. The feeding troughs are used for batch feeding of lead ingots. Partition plates are installed between the feeding troughs to limit the lateral position of the lead ingots, ensuring their proper placement. A baffle is installed at one end of each partition plate to limit the front-back position of the lead ingots, ensuring that the lead ingots correspond to the feeding troughs. This design effectively controls the position of the lead ingots.
[0012] Preferably, the sealing assembly includes a sealing plate, a lead screw, and a motor. Several sealing assemblies are provided, with each feeding slot corresponding to a different slot. The sealing plate matches the feeding slot, with one end of the sealing plate passing through a baffle and positioned on the other side of the baffle. One end of the lead screw is threadedly connected to the sealing plate. The motor is mounted on a stacking plate, and its shaft is connected to the lead screw. The sealing plate of the sealing assembly is placed on the stacking plate, sealing the feeding slot and ensuring that the lead ingots placed on the sealing block will not fall. A threaded hole is provided on the sealing plate, and one end of the lead screw is placed in the threaded hole. The motor drives the lead screw to rotate, and the threaded engagement between the lead screw and the threaded hole rotates the sealing plate. Since one end of the sealing plate passes through the baffle, it can only move linearly under the baffle's restriction. Therefore, the sealing plate can be moved to open the feeding slot. The lead ingots are restricted by the baffle, allowing them to gradually feed from the feeding slot. This design allows for the opening and closing of the feeding slot.
[0013] Preferably, a limiting rod is provided on one side of the baffle, the limiting rod is connected to the stacking plate, and the limiting rod is in contact with the top surface of the sealing plate. The limiting rod is installed on one end of the baffle for pulling out the sealing plate. The limiting rod is installed on the stacking plate, and the limiting rod is in contact with the sealing plate, which can support the sealing plate and ensure the contact between the sealing plate and the stacking plate. This design can restrict the sealing plate.
[0014] Preferably, the lifting assembly includes a column, a pneumatic cylinder, and a lifting plate. The upper end of the column is connected to the pneumatic cylinder, and the lower end of the pneumatic cylinder is connected to the lifting plate. The column of the lifting assembly is installed on the ground, supporting and lifting the pallet. The pneumatic cylinder installed at the top of the column then drives the lifting plate to move up and down, thus lifting the pallet. The lifting plate uses a corner assembly to lift and lower the pallet. This design enables the pallet to be lifted and lowered.
[0015] Preferably, the corner assembly includes a rotating plate, a connecting frame, and a second motor. The rotating plate is rotatably connected to the lifting plate. Connecting frames are installed on both sides of the rotating plate, and the connecting frames have a U-shaped cross-section. The two ends of the connecting frames are connected to the two sides of the stacking plate, respectively. The second motor is mounted on the lifting plate, and a first gear is mounted on the motor shaft of the second motor. A crown gear is mounted on the rotating plate, and the first gear meshes with the crown gear. When placing lead ingots, the second motor drives the first gear to rotate, and the meshing of the first gear with the crown gear drives the rotating plate on the lifting plate to rotate. The connecting frame is mounted on the rotating plate and is connected to the end of the stacking plate with the feeding groove. The U-shaped connecting frame connects to the stacking plate, improving the stability of the stacking plate. This design allows the stacking plate to rotate.
[0016] The beneficial effects of this utility model are: it can turn lead ingots and place them in a staggered manner, it can restrict the position of lead ingots, it can open and close the feeding chute, it can restrict the sealing plate, it can realize the lifting and lowering of the stacking plate, and it can rotate the stacking plate. Attached Figure Description
[0017] Figure 1 This is a schematic diagram of the structure of this utility model;
[0018] Figure 2 yes Figure 1 Schematic diagram of the structure of the palletizing plate;
[0019] Figure 3 yes Figure 1 Schematic diagram of the middle sealing component;
[0020] Figure 4 yes Figure 1 A schematic diagram of the structure of the corner component.
[0021] In the diagram: 1. Palletizing plate; 11. Feed chute; 12. Divider plate; 13. Baffle plate; 14. Limiting rod; 2. Sealing assembly; 21. Sealing plate; 22. Lead screw; 23. Motor 1; 3. Corner assembly; 31. Rotating plate; 32. Connecting frame; 33. Motor 2; 34. Gear 1; 35. Crown gear; 4. Lifting assembly; 41. Column; 42. Pneumatic cylinder 1; 43. Lifting plate. Detailed Implementation
[0022] The present invention will be further described below with reference to the accompanying drawings and specific embodiments.
[0023] like Figure 1 In the illustrated embodiment, a lead ingot stacking device includes:
[0024] The pallet 1 has several material feeding troughs 11.
[0025] Blocking component 2 is installed on the palletizing plate 1 and corresponds to the unloading chute 11.
[0026] Corner assembly 3, which is connected to palletizing plate 1;
[0027] Lifting component 4 is connected to corner component 3.
[0028] like Figure 2 As shown, a number of feeding troughs 11 are evenly distributed at one end of the pallet 1. A partition plate 12 is installed on both sides of the feeding trough 11. A baffle plate 13 is installed on the pallet 1. The end of the partition plate 12 away from the end of the pallet 1 is connected to the partition plate 12.
[0029] like Figure 3 As shown, the sealing assembly 2 includes a sealing plate 21, a lead screw 22, and a motor 23. The sealing assembly 2 has several of these components, and each of them corresponds to a feeding trough 11. The sealing plate 21 is matched with the feeding trough 11. One end of the sealing plate 21 passes through the baffle 13 and is placed on the other side of the baffle 13. One end of the lead screw 22 is threadedly connected to the sealing plate 21. The motor 23 is mounted on the palletizing plate 1, and the motor shaft of the motor 23 is connected to the lead screw 22.
[0030] A limiting rod 14 is provided on one side of the baffle 13. The limiting rod 14 is connected to the stacking plate 1 and is in contact with the top surface of the sealing plate 21.
[0031] like Figure 4 As shown, the lifting assembly 4 includes a column 41, a pneumatic cylinder 42, and a lifting plate 43. The upper end of the column 41 is connected to the pneumatic cylinder 42, and the lower end of the pneumatic cylinder 42 is connected to the lifting plate 43.
[0032] The corner assembly 3 includes a rotating plate 31, a connecting frame 32, and a second motor 33. The rotating plate 31 is rotatably connected to the lifting plate 43. The connecting frame 32 is installed on both sides of the rotating plate 31. The cross-sectional shape of the connecting frame 32 is U-shaped. The two ends of the connecting frame 32 are respectively connected to the two sides of the stacking plate 1. The second motor 33 is installed on the lifting plate 43. A first gear 34 is installed on the motor shaft of the second motor 33. A crown gear 35 is installed on the rotating plate 31. The first gear 34 meshes with the crown gear 35.
[0033] Lead ingots are conveyed between two partition plates 12 on the palletizing plate 1 by a conveying device. The lead ingots are then arranged on the sealing plate 21. Then, the second motor 33 rotates, and the meshing of the first gear 34 and the crown gear 35 drives the rotating plate 31 to rotate. The rotating plate 31 drives the palletizing plate 1 to adjust its angle through the connecting frame 32 to ensure the stacking direction of the lead ingots. Then, the first motor 23 is activated, which drives the lead screw 22 to rotate. The lead screw 22 pulls the sealing plate 21 to move through its threaded connection with the sealing plate 21, pulling the sealing plate 21 out from one side of the baffle 22, opening the feeding trough 11. Then, the lead ingots are fed through the feeding trough 11 to complete the stacking of the lead ingots. Finally, the palletizing plate 1 is lifted by the first pneumatic cylinder 42 and the lead ingots are stacked again.
Claims
1. A lead ingot piling device, characterized by, include: The palletizing plate (1) is provided with a plurality of feeding troughs (11). A sealing assembly (2) is installed on the palletizing plate (1) and corresponds to the feeding chute (11); Corner assembly (3), the corner assembly (3) is connected to the palletizing plate (1); The lifting assembly (4) is connected to the corner assembly (3).
2. The lead ingot piling device according to claim 1, wherein, The palletizing plate (1) has several feeding slots (11) evenly distributed at one end. Both sides of the feeding slots (11) are equipped with partition plates (12). The palletizing plate (1) is equipped with a baffle (13). The end of the partition plate (12) away from the end of the palletizing plate (1) is connected to the partition plate (12).
3. The lead ingot piling device according to claim 2, wherein, The sealing assembly (2) includes a sealing plate (21), a lead screw (22) and a motor (23). The sealing assembly (2) is provided with several of them and the feeding grooves (11) correspond one to one. The sealing plate (21) matches the feeding groove (11). One end of the sealing plate (21) passes through the baffle (13) and is placed on the other side of the baffle (13). One end of the lead screw (22) is threadedly connected to the sealing plate (21). The motor (23) is installed on the palletizing plate (1). The motor shaft of the motor (23) is connected to the lead screw (22).
4. The lead ingot piling device according to claim 3, wherein, A limiting rod (14) is provided on one side of the baffle (13). The limiting rod (14) is connected to the stacking plate (1) and the limiting rod (14) is in contact with the top surface of the sealing plate (21).
5. The lead ingot piling device according to claim 1, wherein, The lifting assembly (4) includes a column (41), a pneumatic cylinder (42) and a lifting plate (43). The upper end of the column (41) is connected to the pneumatic cylinder (42), and the lower end of the pneumatic cylinder (42) is connected to the lifting plate (43).
6. A lead ingot piling device according to claim 5, wherein The corner assembly (3) includes a rotating plate (31), a connecting frame (32), and a second motor (33). The rotating plate (31) is rotatably connected to the lifting plate (43). The connecting frame (32) is installed on both sides of the rotating plate (31). The cross-sectional shape of the connecting frame (32) is U-shaped. The two ends of the connecting frame (32) are respectively connected to the two sides of the stacking plate (1). The second motor (33) is installed on the lifting plate (43). A gear (34) is installed on the motor shaft of the second motor (33). A crown gear (35) is installed on the rotating plate (31). The gear (34) meshes with the crown gear (35).