Vertical anode plate beam pouring device
By designing support and clamping components for the vertical anode plate beam casting device, and utilizing hydraulic pushers to achieve rapid connection and disassembly of the mold, and by incorporating collection components to facilitate residue cleaning, the problems of inconvenient mold connection and difficult cleaning in the existing mold system are solved, thereby improving casting efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HUNAN JIHANG NEW MATERIAL TECHNOLOGY CO LTD
- Filing Date
- 2025-06-30
- Publication Date
- 2026-06-19
AI Technical Summary
The existing casting beam molds are inconvenient to connect and disassemble, difficult to clean up residue, and inconvenient to move, which affects the casting efficiency.
A vertical anode plate beam casting device is designed, including a support assembly, a clamping assembly, and a collection component. The moving mold mounting component is driven to move by a hydraulic pusher, so that the upper mold and the lower mold can be detachably connected or separated. The collection component is provided to facilitate the cleaning of residue.
It enables rapid connection and disassembly of the upper and lower molds, simplifies the residue cleaning process, and improves the casting efficiency of the anode plate beam.
Smart Images

Figure CN224374404U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of casting mold technology, specifically to a vertical anode plate beam casting device. Background Technology
[0002] Currently, the main types of casting molds are upper and lower molds combined. The upper and lower molds are connected by snap-fit or bolts. After casting, the upper and lower molds are disassembled to remove the finished product and clean up the residue. Then, the upper and lower molds are reassembled for a new round of casting. However, during the casting process, the molds themselves are heavy and inconvenient to move, which makes it time-consuming to connect and disassemble the upper and lower molds, and it is also inconvenient to clean up the residue.
[0003] Utility model patent CN215879747U discloses an embedded anode plate conductive beam mold, including an upper mold and a lower mold. The upper mold is located to the right of the lower mold. The upper mold has an upper mold opening at its upper end, and a semi-circular strip plate is fixed to the upper inner side of the upper mold opening away from the lower mold. The lower mold has a lower mold opening at its upper end, and a strip plate is fixed to the upper inner side of the lower mold away from the upper mold. A beam body is arranged inside the lower mold opening. Welding cylinders are fixed on the side walls of the lower mold and the upper mold in opposite directions. Three welding cylinders are linearly and evenly distributed on both the upper and lower molds. Two adjacent welding cylinders on the upper and lower molds are staggered. Rotary insert rods and rotating connecting rods are respectively arranged inside the two adjacent welding cylinders. Movable holes are formed on the inner sides of the opposite ends of the two adjacent rotating insert rods and rotating connecting rods. The upper and lower ends of the movable holes... Each mold has a limiting hole through which the corresponding rotating insert rod and rotating connecting rod pass. A locking rod is installed inside each limiting hole, and a locking hole is provided on the surface of the welding cylinder near the locking rod. With the locking rod and locking hole, the rotating insert rod and rotating connecting rod connect two adjacent welding cylinders together. Therefore, when disassembling the upper and lower molds, only the locking rod needs to be moved out of the locking hole, thus eliminating the locking rod's limiting effect on the welding cylinder. The rotating connecting rod and rotating insert rod can then be directly moved out of the welding cylinder, separating the upper and lower molds, facilitating assembly and disassembly. However, in this patent, the integrated design is prone to damage with repeated use, and the upper mold needs to be flipped after each pour to separate it from the lower mold. Because the molds themselves are heavy and difficult to move, the connection and disassembly of the upper and lower molds are time-consuming.
[0004] Utility model patent CN218315428U discloses a one-time extrusion molding die for a 3.2㎡ cathode plate conductive beam, including a lower die. The upper end of the lower die has a cover plate. The lower die has a mold air hole on its lower interior side. Through holes are formed at all four corners of the cover plate. Mounting holes are formed at the upper end of the lower die corresponding to the through holes. Threaded rods are formed at the upper end of the cover plate corresponding to the through holes. Locking plates are screwed onto the outer side walls of the threaded rods. Mounting rods are fixed to the lower side of each threaded rod. Moving blocks are fixed to the outer side walls of the lower portion of each mounting rod, with two moving blocks evenly distributed on each mounting rod. Annular grooves are formed on the outer side walls below the mounting holes. Rotating the threaded rods facilitates the movement of the moving blocks within the annular grooves, thus facilitating the removal of the mounting rods. The height of the moving blocks is the same as the height of the annular grooves, making it easy to move the moving blocks into the annular grooves. However, disassembly and cleaning are difficult. Utility Model Content
[0005] The main purpose of this utility model is to provide a vertical anode plate beam casting device to solve the problems of inconvenient connection and disassembly of existing beam casting molds and inconvenient residue cleaning.
[0006] To achieve the above objectives, this utility model provides a vertical anode plate crossbeam casting device, comprising:
[0007] The support assembly includes a bottom support, fixing members spaced apart on the bottom support, and a stationary mold mounting member; an operating space is formed between the fixing members and the stationary mold mounting member, and a guide member is provided between the fixing members and the stationary mold mounting member; a collecting member is provided below the operating space;
[0008] The clamping assembly includes a moving mold mounting component slidably disposed on a guide member and a pushing component disposed on a bottom support member; the pushing component is connected to the moving mold mounting component; the upper mold and the lower mold are detachably connected to the stationary mold mounting component and the moving mold mounting component, respectively; the pushing component reciprocates under the action of an external force, so that the moving mold mounting component moves toward or away from the stationary mold mounting component, thereby causing the upper mold and the lower mold to abut or separate; the guide member is arranged parallel to the horizontal plane so that the end faces of the upper mold and the lower mold are perpendicular to the horizontal plane when they abut.
[0009] As a further improvement of this utility model, the bottom support includes a bottom support plate; the bottom support plate is provided with a leveling screw, and the leveling screw is provided with a leveling washer.
[0010] As a further improvement of this utility model, the fixing member includes a fixing plate disposed on the bottom support plate; the static mold mounting member includes a static mold mounting plate disposed on the bottom support plate; and a first water cooling pipe is provided inside the static mold mounting plate.
[0011] As a further improvement of this utility model, the guide member includes multiple sets of guide rods that are respectively connected at both ends to the fixed plate and the static mold mounting plate.
[0012] As a further improvement of this utility model, the moving mold mounting component includes a moving mold mounting plate slidably disposed on the guide rod; a second water cooling pipe is provided inside the moving mold mounting plate.
[0013] As a further improvement of this utility model, the pushing component includes a hydraulic pushing rod disposed on the bottom support plate and a hydraulic cylinder connected to the hydraulic pushing rod; one end of the hydraulic pushing rod passes through the fixed plate and is connected to the moving mold mounting plate.
[0014] As a further improvement of this utility model, the collecting component includes a collecting plate disposed at the bottom end of the moving mold mounting plate; the bottom support plate is provided with a collecting groove located below the operating space; the collecting plate is located in the collecting groove.
[0015] The beneficial effects of this utility model are reflected in:
[0016] By setting up bottom support components, fixing components, and static mold mounting components to provide support for the pushing component and moving mold mounting component, the upper mold and lower mold can be installed on the static mold mounting component and moving mold mounting component respectively. The pushing component drives the moving mold mounting component to move, so that the lower mold and the upper mold can be fitted together to cast the anode plate beam, or the lower mold and the upper mold can be separated to remove the cast anode plate beam. This makes the connection and disassembly between the upper mold and the lower mold convenient and quick. At the same time, the upper mold and the lower mold are in a vertical state, which facilitates the cleaning of internal residues and the continuation of a new round of anode plate beam casting, thereby improving the casting efficiency of anode plate beams. Attached Figure Description
[0017] Figure 1 This is a schematic diagram of the planar structure of a vertical anode plate beam casting device according to the present invention;
[0018] Figure 2 This is a schematic diagram of the structure of a vertical anode plate beam casting device after the upper and lower molds are installed;
[0019] Figure 3 This is a schematic diagram of the overall structure of a vertical anode plate beam casting device according to the present invention.
[0020] Figure 4 This is a schematic diagram of the bottom support structure of a vertical anode plate beam casting device according to the present invention;
[0021] Figure 5 This is a schematic diagram of the moving mold mounting component of a vertical anode plate beam casting device according to this utility model;
[0022] Explanation of reference numerals in the attached figures:
[0023] 1. Bottom support component; 101. Bottom support plate; 2. Fixing component; 201. Fixing plate; 3. Static mold mounting component; 301. Static mold mounting plate; 4. Operating space; 5. Guide component; 501. Guide rod; 502. Nut; 6. Collecting component; 601. Collecting plate; 602. Inclined surface; 7. Moving mold mounting component; 701. Moving mold mounting plate; 8. Pushing component; 801. Hydraulic push rod; 802. Hydraulic cylinder; 9. Upper mold; 10. Lower mold; 11. Leveling screw; 12. Leveling shim; 13. Adjusting plate; 14. 15. Leveling screw hole; 16. First water-cooling pipe; 17. Lifting lug; 18. Lifting rod; 19. Second water-cooling pipe; 20. Sliding hole; 21. Sliding sleeve; 22. First flange; 23. Second flange; 24. Hydraulic oil tank; 25. Oil pump; 26. Motor; 27. Electrical box; 28. Hydraulic oil water-cooling device; 29. Valve group; 30. Connecting hole; 31. Screw; 32. Collection tank; 33. First limit switch; 34. Second limit switch; 35. Stroke plate; 36. First stroke rod; 37. Second stroke rod; 38. Limit rod. Detailed Implementation
[0024] To make the objectives, technical solutions, and advantages of this utility model clearer, the present utility model will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the described embodiments are merely some, not all, of the embodiments of this utility model. Unless otherwise specified, the embodiments and features described in this application can be combined with each other. All other embodiments obtained by those skilled in the art based on the embodiments of this utility model without creative effort are within the scope of protection of this utility model.
[0025] In one embodiment, see Figure 1 The present invention relates to a vertical anode plate beam casting device, comprising an upper mold 9, a lower mold 10, a support assembly, and a clamping assembly.
[0026] The support assembly includes a bottom support 1, a fixing member 2 spaced apart on the bottom support 1, and a stationary mold mounting member 3. An operating space 4 is formed between the fixing member 2 and the stationary mold mounting member 3. A guide member 5 is provided between the fixing member 2 and the stationary mold mounting member 3. A collecting member 6 is provided below the operating space 4. The clamping assembly includes a moving mold mounting member 7 slidably disposed on the guide member 5 and a pushing member 8 disposed on the bottom support 1. The pushing member 8 is connected to the moving mold mounting member 7. The upper mold 9 and the lower mold 10 are detachably connected to the stationary mold mounting member 3 and the moving mold mounting member 7, respectively. The pushing member 8 reciprocates under the action of external force, so that the moving mold mounting member 7 moves toward or away from the stationary mold mounting member 3, thereby causing the upper mold 9 and the lower mold 10 to abut or separate. The guide member 5 is arranged parallel to the horizontal plane so that the end face of the upper mold 9 and the lower mold 10 when they abut is perpendicular to the horizontal plane.
[0027] Further, see Figure 2 , 4 The bottom support component 1 includes a bottom support plate 101, a leveling screw 11 on the bottom support plate 101, and a leveling pad 12 on the leveling screw 11.
[0028] Preferably, an adjusting plate 13 is welded to the outer end of the bottom support plate 101, and the adjusting plate 13 is provided with a leveling screw hole 14, and the leveling screw 11 is threadedly connected to the leveling screw hole 14.
[0029] Further, see Figure 2 , 3 The fixing component 2 includes a fixing plate 201 disposed on the bottom support plate 101, and the static mold mounting component 3 includes a static mold mounting plate 301 disposed on the bottom support plate 101. The static mold mounting plate 301 is provided with a first water cooling pipe 15.
[0030] Preferably, the bottom support plate 101 is provided with mounting screw holes at intervals, and the fixing plate 201 and the static mold mounting plate 301 are installed on the bottom support plate 101 at intervals by bolts and threaded connections to the mounting screw holes.
[0031] Preferably, the bottom support plate 101 and the static mold mounting plate 301 are respectively provided with two sets of lifting lugs 16. Since the height of the static mold mounting package is greater than that of the bottom support plate 101, in order to ensure that the four sets of lifting lugs 16 are at the same horizontal height, the bottom support plate 101 is provided with two sets of lifting rods 17, and the two sets of lifting lugs 16 on the bottom support plate 101 are welded to the two sets of lifting rods 17.
[0032] In the above setup, the entire device can be moved to the installation position by using a lifting device connected to the lifting lug 16 via a lifting cable. After the entire device is lifted into place, the leveling screw 11 can be rotated to move the leveling pad 12. By adjusting the height of the bottom support plate 101 supported by the leveling screw 11, the bottom support plate 101 can be adjusted to a horizontal state. During the process of adjusting the bottom support plate 101 to be horizontal, an external level or a bubble level can be installed on the bottom support plate 101 to assist in leveling the bottom support plate 101.
[0033] Further, see Figure 2 , 3 The guide component 5 includes multiple sets of guide rods 501 that are connected at both ends to the fixed plate 201 and the static mold mounting plate 301, respectively.
[0034] Preferably, the fixed plate 201 and the static mold mounting plate 301 are respectively provided with connecting holes 29, and the two ends of the guide rod 501 are respectively provided with connecting threads. The two ends of the guide rod 501 pass through the connecting holes 29 and are connected to the nut 502.
[0035] Preferably, four sets of guide rods 501 are provided, and the guide rods 501 are installed in pairs at both ends of the fixed plate 201 and the static mold mounting plate 301.
[0036] In the above setup, the guide rod 501 is installed on the fixed plate 201 and the stationary mold mounting plate 301 by means of nut 502. In order to avoid the guide rod 501 obstructing the installation of the upper mold 9 and the lower mold 10, the guide rod 501 is installed at both ends of the fixed plate 201 and the stationary mold mounting plate 301.
[0037] Further, see Figure 3 , 4 The moving mold mounting component 7 includes a moving mold mounting plate 701 that is slidably mounted on the guide rod 501, and a second water cooling pipe 18 is provided inside the moving mold mounting plate 701.
[0038] Preferably, the moving mold mounting plate 701 is provided with a sliding hole 19, and a sliding sleeve 20 is provided in the sliding hole 19. The sliding sleeve 20 is clearance-fitted with the guide rod 501.
[0039] It should be noted that four sets of guide rods 501 are provided, with two sets installed at both ends of the fixed plate 201 and the stationary mold mounting plate 301. The sliding holes 19 and sliding sleeves 20 need to be matched with the guide rods 501, so four sets of sliding holes 19 and sliding sleeves 20 need to be provided, and lubricating oil needs to be injected into the sliding sleeves 20 to ensure that the stationary mold fixed plate 201 can slide smoothly on the guide rods 501.
[0040] Further, see Figure 2 , 3 The pusher 8 includes a hydraulic push rod 801 mounted on the bottom support plate 101 and a hydraulic cylinder 802 connected to the hydraulic push rod 801. One end of the hydraulic push rod 801 passes through the fixed plate 201 and is connected to the moving mold mounting plate 701.
[0041] Preferably, the fixing plate 201 is provided with a connecting through hole, the hydraulic push rod 801 passes through the connecting through hole, and the hydraulic cylinder 802 is bolted to the fixing plate 201 through the first flange 21.
[0042] Preferably, the hydraulic push rod 801 is bolted to the moving mold mounting plate 701 via the second flange 22.
[0043] It should be noted that the hydraulic cylinder 802 and the hydraulic push rod 801 are existing structures. In order to ensure the normal operation of the hydraulic cylinder 802 and the hydraulic rod, the bottom support plate 101 should also be equipped with a hydraulic oil tank 23, an oil pump 24, a motor 25, an electrical box 26, a hydraulic oil water cooling device 27, and a valve group 28. These components are existing structures and will not be described in detail.
[0044] Preferably, two sets of hydraulic cylinders 802 and hydraulic push rods 801 are arranged at intervals.
[0045] In the above configuration, the hydraulic cylinder 802 drives the hydraulic push rod 801 to move toward the stationary mold mounting plate 301, thereby causing the moving mold mounting plate 701 to move toward the stationary mold mounting plate 301, thus adjusting the distance between the stationary mold mounting plate 301 and the moving mold mounting plate 701.
[0046] Preferably, the upper mold 9 and the lower mold 10 are provided with connecting screw holes, and the stationary mold mounting plate 301 and the moving mold mounting plate 701 are respectively provided with connecting holes 29. The upper mold 9 and the lower mold 10 can be installed on the stationary mold mounting plate 301 and the moving mold mounting plate 701 by passing through the connecting holes 29 and connecting screw holes, respectively.
[0047] It should be noted that, in order to ensure the docking accuracy of the upper mold 9 and the lower mold 10, coaxial connecting holes 29 are opened on the stationary mold mounting plate 301 and the moving mold mounting plate 701. The upper mold 9 and the lower mold 10 are connected to the stationary mold mounting plate 301 and the moving mold mounting plate 701 respectively by screws 30. After the hydraulic push rod 801 pushes the moving mold mounting plate 701 and moves the lower mold 10, the lower mold 10 abuts against the upper mold 9, thereby making the upper mold 9 and the lower mold 10 fit precisely.
[0048] Further, see Figure 4 , 5 The collecting component 6 includes a collecting plate 601 disposed at the bottom of the moving mold mounting plate 701, and a collecting groove 31 located below the operating space 4 on the bottom support plate 101, with the collecting plate 601 located in the collecting groove 31.
[0049] Preferably, the upper end face of the collecting plate 601 is provided with an inclined surface 602. When the upper mold 9 and the lower mold 10 are in contact, the end of the collecting plate 601 that is away from the moving mold mounting plate 701 extends beyond the stationary mold mounting plate 301.
[0050] In the above configuration, as the moving mold mounting plate 701 drives the lower mold 10 to move toward the stationary mold mounting plate 301, the collecting plate 601 moves accordingly within the collecting groove 31, pushing the residue in the collecting groove 31 to the outside of the stationary mold mounting plate 301, thus facilitating the removal of residue. When the moving mold mounting plate 701 moves away from the stationary mold mounting plate 301, the collecting plate 601 moves toward the fixed plate 201. After the cast anode plate beam is removed, the casting cavities on the vertical upper mold 9 and lower mold 10 are exposed, facilitating the removal of residue from the casting cavities. During the removal process, the residue falls into the collecting groove 31, and the inclined surface 602 on the collecting plate 601 can guide the residue into the collecting groove 31, preventing residue from accumulating on the collecting plate 601.
[0051] Further, see Figure 2A first limit switch 32 and a second limit switch 33 are spaced apart on the fixed plate 201. A stroke plate 34 is provided on the moving mold mounting plate. The stroke plate is provided with a first stroke rod 35 corresponding to the first limit switch 32 and a second stroke rod 36 corresponding to the second limit switch 33. The stroke plate 34 moves with the moving mold mounting plate 701 toward the stationary mold mounting plate 301 so that the second stroke rod 36 abuts against the second limit switch 33, controlling the moving distance of the moving mold mounting plate 701 toward the stationary mold mounting plate 301. The stroke plate 34 moves with the moving mold mounting plate 701 toward the fixed plate 201 so that the first stroke rod 35 abuts against the first limit switch 32, controlling the moving distance of the moving mold mounting plate 701 toward the fixed plate 201.
[0052] Preferably, the travel plate 34, the first travel switch 32, and the second travel switch 33 are respectively connected to the moving mold mounting plate 701 and the fixing plate 201 by bolts.
[0053] Preferably, there is a gap between the first limit switch 32 and the second limit switch 33, and the first limit rod 35 and the second limit rod 36 are arranged in parallel with a gap between their axes.
[0054] In the above configuration, a control handle is installed on the outside of the hydraulic cylinder 802. The handle is equipped with a mold closing button and a mold opening button. During the mold closing process, pressing the mold closing button puts the hydraulic cylinder 802 into the oil supply stage, causing the hydraulic push rod 801 to move and push the moving mold mounting plate 701 toward the stationary mold mounting plate 301. The second stroke rod 36 then moves toward the stationary mold mounting plate 301. After the moving mold mounting plate 701 and the stationary mold mounting plate 301 are in close contact, the second stroke rod 36 pushes the second stroke switch to operate. The second stroke switch 33 controls the hydraulic cylinder 802 to disconnect the oil supply. At this time, the moving mold mounting plate 701 and the stationary mold mounting plate 301 are in contact. When the first stroke rod 35 separates from the first stroke switch 32, the anode plate beam can be cast. After the anode plate beam is cast, press the mold opening button. The hydraulic cylinder 802 is in the oil return stage, which causes the hydraulic push rod 801 to move the moving mold mounting plate 701 toward the fixed plate 201. The second stroke rod 36 separates from the second stroke switch 33. The first stroke rod 35 pushes the first stroke switch 32 to act and controls the hydraulic cylinder 802 to disconnect the oil supply. At this time, the moving mold mounting plate 701 moves away from the stationary mold mounting plate 301, and the second stroke rod 36 separates from the second stroke switch 33, so the cast anode plate beam can be taken out.
[0055] Further, see Figure 2To control the force exerted when the moving mold mounting plate 701 and the stationary mold mounting plate 301 are in close contact, the stationary mold mounting plate 301 is provided with a limiting rod 37, and the moving mold mounting plate 701 is provided with a limiting hole that cooperates with the limiting rod 37. The length of the limiting rod 37 is the same as the depth of the limiting hole. After the moving mold mounting plate 701 is pushed against the stationary mold mounting plate 301 by the hydraulic push rod 801, the limiting rod 37 is inserted into the limiting hole, and the force can be transferred to the limiting rod 37.
[0056] In this embodiment, after the upper mold 9 and lower mold 10 are respectively installed on the stationary mold mounting plate 301 and the moving mold mounting plate 701, the hydraulic cylinder 802 drives the hydraulic rod to move the moving mold mounting plate 701 and the lower mold 10 toward the upper mold 9, so that the lower mold 10 abuts against the upper mold 9. The second stroke rod 36 cooperates with the second stroke switch 33 to control the movement distance of the hydraulic push rod 801 and control the tightness of the lower mold 10 against the upper mold 9, so that the upper mold 9 and lower mold 10 do not need to be connected by external bolts. After the casting liquid is poured into the mold, it is connected to the first water cooling pipe 15 and the second water cooling pipe 16. The water pump connected to pipe 18 supplies water for cooling, which allows the anode plate beam to cool down and form quickly after casting. After the anode plate beam is formed, the hydraulic push rod 801 drives the moving mold mounting plate 701 and the lower mold 10 to move in the upper mold 9. The moving distance of the moving mold mounting plate 701 is controlled by the first stroke rod 35 and the first stroke switch 32, separating the upper mold 9 and the lower mold 10. The workers take out the formed anode plate beam and clean the residue on the upper mold 9 and the lower mold 10 into the collection tank 31. The lower mold 10 is driven to contact the upper mold 9 again, and a new round of anode plate beam casting can be carried out.
[0057] In this embodiment, the mold closing thrust is 60 tons, the mold opening pull force is 30 tons, the minimum mold closing thickness is 50 mm, the maximum opening is 250 mm, the hydraulic cylinder 802 has a stroke of 200 mm, the operating pressure is 25 MPa, the motor power is 7.5 kW, and the oil tank volume is 350 liters.
[0058] The above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.
Claims
1. A vertical anode plate beam pouring device, comprising an upper mold (9) and a lower mold (10); characterized in that, Also includes: The support assembly includes a bottom support (1), a fixing member (2) spaced apart on the bottom support (1), and a stationary mold mounting member (3); an operating space (4) is formed between the fixing member (2) and the stationary mold mounting member (3), and a guide member (5) is provided between the fixing member (2) and the stationary mold mounting member (3); a collecting member (6) is provided below the operating space (4). The clamping assembly includes a moving mold mounting component (7) slidably disposed on a guide component (5) and a pushing component (8) disposed on a bottom support component (1); the pushing component (8) is connected to the moving mold mounting component (7); the upper mold (9) and the lower mold (10) are respectively detachably connected to the stationary mold mounting component (3) and the moving mold mounting component (7); the pushing component (8) reciprocates under the action of external force, so that the moving mold mounting component (7) moves toward or away from the stationary mold mounting component (3), thereby causing the upper mold (9) and the lower mold (10) to abut or separate; the guide component (5) is arranged parallel to the horizontal plane so that the end faces of the upper mold (9) and the lower mold (10) are perpendicular to the horizontal plane when they abut.
2. The vertical anode plate beam pouring device according to claim 1, characterized in that: The bottom support member (1) includes a bottom support plate (101); the bottom support plate (101) is provided with a leveling screw (11), and the leveling screw (11) is provided with a leveling pad (12).
3. The vertical anode plate beam pouring device according to claim 2, characterized in that: The fixing component (2) includes a fixing plate (201) disposed on the bottom support plate (101); the static mold mounting component (3) includes a static mold mounting plate (301) disposed on the bottom support plate (101); the static mold mounting plate (301) is provided with a first water cooling pipe (15).
4. The vertical anode plate beam pouring device according to claim 3, characterized in that: The guide component (5) includes multiple sets of guide rods (501) that are connected at both ends to the fixed plate (201) and the static mold mounting plate (301) respectively.
5. The vertical anode plate beam pouring device according to claim 4, characterized in that: The moving mold mounting component (7) includes a moving mold mounting plate (701) slidably disposed on a guide rod (501); a second water cooling pipe (18) is provided inside the moving mold mounting plate (701).
6. The vertical anode plate beam pouring device according to claim 5, characterized in that: The pusher (8) includes a hydraulic push rod (801) mounted on the bottom support plate (101) and a hydraulic cylinder (802) connected to the hydraulic push rod (801); one end of the hydraulic push rod (801) passes through the fixing plate (201) and is connected to the moving mold mounting plate (701).
7. The vertical anode plate beam pouring device according to claim 6, characterized in that: The collecting component (6) includes a collecting plate (601) disposed at the bottom of the moving mold mounting plate (701); the bottom support plate (101) is provided with a collecting groove (31) located below the operating space (4); the collecting plate (601) is located in the collecting groove (31).