CN118143210A - Hot melting casting equipment for processing aluminum-zinc-strontium mixed plating material - Google Patents

Abstract

The invention relates to the technical field of aluminum zinc strontium mixed plating material processing, in particular to hot melting casting equipment for aluminum zinc strontium mixed plating material processing, which comprises a support frame, wherein a smelting furnace is arranged in the middle of the support frame, a casting structure is connected between the smelting furnace and the support frame, a positioning structure is arranged in the middle of the support frame, a separating structure is arranged on one side of the support frame, a fixing structure is arranged on the other side of the support frame, a cleaning structure is connected between the casting structure and the support frame, and a supporting structure is arranged on the side surface of the support frame; can reduce the workman through casting structure and carry out the safe risk of ingot casting in-process, can adjust the receipt position of mould through location structure, can reduce the damage of drawing of patterns to mould or work piece through separation structure, can fix a position the mould that needs the drawing of patterns through fixed knot constructs, can conveniently clear up the loading board through clearance structure, make things convenient for the workman to carry out the interpolation of metal material to the smelting pot through bearing structure.

Description

Hot melting casting equipment for processing aluminum-zinc-strontium mixed plating material

Technical Field

The invention relates to the technical field of aluminum zinc strontium mixed plating material processing, in particular to hot melting casting equipment for aluminum zinc strontium mixed plating material processing.

Background

The hot dipping is to put the cleaned workpiece into melted hot dipping material, take out the workpiece after isothermal, and wrap thicker hot dipping material on the surface of the workpiece, thereby improving the corrosion resistance of the workpiece. The aluminum zinc strontium mixed plating material is one of hot-dip materials, when the aluminum zinc plating material is produced, the hot-dip materials are required to be melted and cast into a metal ingot form, and when the aluminum zinc strontium mixed plating material is required to be used, the metal ingot of the hot-dip materials is required to be remelted for carrying out a hot-dip process of a workpiece.

However, in the process of casting a hot-dip material into a metal ingot, because the hot-dip material in a molten state is easy to splash in the pouring process, potential safety hazards are formed for operators, meanwhile, the demolding of the metal ingot usually needs to be manually knocked and demolded by workers, and damages to a workpiece and even a mold are possibly caused due to uneven force, on the other hand, a large amount of metal scraps are usually left on a platform in the production process, and the cleaning is inconvenient.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides hot melting casting equipment for processing an aluminum-zinc-strontium mixed plating material.

The technical scheme adopted for solving the technical problems is as follows: the utility model provides a hot melt casting equipment that aluminium zinc strontium mixed plating material processing was used, includes the support frame, the middle part of support frame is equipped with the smelting pot, be connected with casting structure between smelting pot and the support frame, the middle part of support frame is equipped with location structure, one side of support frame is equipped with separating structure, the opposite side of support frame is equipped with fixed knot constructs, be connected with clearance structure between casting structure and the support frame, the side of support frame is equipped with bearing structure.

Specifically, the casting structure includes the loading board, the middle part sliding connection of support frame has the loading board, the tip fixedly connected with rack of loading board, rotate between smelting pot and the support frame and be connected, the fan-shaped pinion rack of both sides fixedly connected with of smelting pot, mesh mutually between rack and the fan-shaped pinion rack, the bottom side of loading board is equipped with the connecting block, the middle part threaded connection of connecting block has the lead screw, rotate between lead screw and the support frame and be connected, be equipped with first mould and second mould on the loading board.

Specifically, the motor is installed to the tip of support frame, through shaft coupling fixed connection between the tip of motor and the lead screw, inconsistent between first mould and the second mould, the tip fixedly connected with conflict piece of loading board, conflict piece is inconsistent with first mould and second mould, the arc groove has been seted up to the side of support frame, the side fixedly connected with traveller of fan-shaped pinion rack, the traveller passes through sliding connection between arc groove and the support frame.

Specifically, location structure is including blocking the pin, the inboard of support frame is equipped with and blocks the pin, the cooperation groove has been seted up respectively to the side of first mould and second mould, the tip sliding connection that blocks the pin that first mould and second mould set up through cooperation groove and homonymy respectively, the side of first mould and second mould is inconsistent with the support frame.

Specifically, the tip sliding connection who blocks the pole has the control lever, fixedly connected with first spring between control lever and the blocking lever, sliding connection between control lever and the support frame, the side fixedly connected with reference column of control lever, a plurality of first constant head tanks have been seted up to the inboard of support frame, the reference column passes through first constant head tank and the looks block of support frame.

Specifically, the separation structure comprises a pry bar, the side of support frame is rotationally connected with the pry bar, fixedly connected with torsional spring between pry bar and the support frame, the restriction groove has been seted up at the middle part of pry bar, the pry bar has a traction block through restriction groove sliding connection, the tip of traction block sets up perpendicularly with the support frame, just sliding connection between traction block and the support frame, the guide way has all been seted up to the side of first mould and second mould.

Specifically, fixed knot constructs including the installation piece, the inboard perpendicular fixedly connected with installation piece of support frame, the installation piece is located on the same straight line with the traction block, the tip sliding connection of installation piece has the button head post, fixedly connected with sixth spring between button head post and the installation piece, the second constant head tank has been seted up to the side of first mould.

Specifically, the clearance structure includes the support chute, the support chute has been seted up respectively to the both sides of support frame, rotate between loading board and the connecting block and be connected, sliding connection between the bottom side of loading board and the support frame, the inboard sliding connection of support frame has the lifting rod, the tip rotation of lifting rod is connected with the supporting wheel, the supporting wheel offsets with the bottom side of loading board and contacts, the locking groove has been seted up to the side of lifting rod, the inboard sliding connection of support frame has the sloping piece, fixedly connected with fourth spring between sloping piece and the support frame, the sloping of sloping piece is contradicted and is had the squeeze lever, the tip of squeeze lever is the inclined plane structure, the tip of squeeze lever is inconsistent with the bottom side of loading board.

Specifically, the tooth's socket has been seted up to the side of lifting rod, the inboard rotation of support frame is connected with the actuating lever, the both ends of actuating lever are fixedly connected with gear respectively, the gear meshes with the lifting rod through the tooth's socket, the tip rotation of actuating lever is connected with the rocker, the ratchet groove has been seted up to the inboard of rocker, the side sliding connection of actuating lever has the ratchet piece, fixedly connected with fifth spring between ratchet piece and the actuating lever, the ratchet piece meshes with the rocker through the ratchet groove.

Specifically, bearing structure includes the platen, the side of support frame rotates to be connected with the platen, the tip sliding connection of platen has the block, fixedly connected with second spring between block and the platen, the block groove has been seted up to the side of support frame, be equipped with the connecting rod between platen and the support frame, rotate between connecting rod and the support frame to be connected, sliding connection between connecting rod and the platen.

Specifically, the side fixedly connected with supporting shoe of support frame, the supporting shoe is inconsistent with the bottom side of platen, the side sliding connection of support frame has the kicking block, fixedly connected with third spring between kicking block and the support frame.

The beneficial effects of the invention are as follows:

(1) According to the hot melting casting equipment for processing the aluminum-zinc-strontium mixed plating material, the casting structure is connected between the melting furnace and the supporting frame, the middle part of the supporting frame is provided with the positioning structure, the safety risk of workers in the process of casting a metal ingot can be reduced through the casting structure, the receiving position of a die can be adjusted through the positioning structure, and the casting is ensured to be performed correctly, namely: firstly, a motor at the end part of a support frame is electrically connected with an external power supply, a screw rod can be driven to rotate through the power supply, then a bearing plate is driven to slide in the middle part of the support frame, the middle part of the bearing plate is used for placing a first die and a second die, the first die and the second die are spliced together to shape a metal ingot, after the end part of a complete die is abutted against a supporting block at the end part of the bearing plate, the motor is started to drive the bearing plate to move towards a smelting furnace through a connecting block, the smelting furnace is internally provided with molten metal plating, along with the movement of the bearing plate, racks at the end part of the bearing plate are meshed with sector toothed plates at the side surface of the smelting furnace, so that the smelting furnace is driven to start to rotate, when the smelting furnace is dumped, the dies are moved to the vicinity of a smelting furnace opening to receive the molten metal until the smelting furnace is reset through the motor after the dumping of the smelting furnace is completed, the situation that workers are directly approaching to the smelting furnace is avoided, the production safety is improved, and for the melting furnace filled with molten metal, the rotating position of the melting furnace is close to the pouring opening, so that the pouring of the molten metal is more controllable, meanwhile, the sliding columns arranged on the side surfaces of the sector toothed plates slide in the arc grooves on the inner side of the supporting frame, the rotation of the melting furnace is limited, the stability of the melting furnace in a static state is improved, under the condition that the quantity of the molten metal in the melting furnace is different, the rotating angle of the melting furnace needs to be correspondingly adjusted when the pouring is carried out, at the moment, in order to enable the mold to correctly receive the molten metal, a user can adjust the final stop position of the mold through the control rod arranged on the side surfaces of the supporting frame, the positioning columns at the end parts of the control rod can be separated from the first positioning grooves on the inner side of the supporting frame by pressing the control rod on any side, and then the control rod is released after being slid to the proper position, under the promotion of first spring, the reference column again with the first constant head tank looks block that corresponds now to fix the position of blocking the pole, the cooperation groove has all been seted up to the side of first mould and second mould, when the mould moved to the pole position that blocks along with the loading board, the tip that blocks the pole can slide into the cooperation inslot until contradicting, thereby block the mould to continue to remove, the loading board continues to remove then can drive the rotation of smelting pot this moment, so, can adjust the final stop position of mould through the position that the adjustment blocked the pole, guarantee the accuracy of casting.

(2) According to the hot melting casting device for processing the aluminum-zinc-strontium mixed plating material, provided by the invention, one side of the support frame is provided with the separation structure, the other side of the support frame is provided with the fixing structure, the cooled die can be separated through the separation structure, the damage to the die or a workpiece is reduced, and the die needing to be demoulded can be positioned through the fixing structure, namely: after casting of the die is completed, the bearing plate is moved reversely through the motor, at the moment, the rack at the end part of the bearing plate drives the smelting furnace to reset, then a user can continuously drive the bearing plate to move until the end part of the traction block at the inner side of the support frame slides into the guide groove at the side surface of the second die, at the moment, after the first die at the other side is fixed by the user, the user only needs to beat the pry bar to the outer side, so that the middle part of the pry bar pulls the traction block, and can provide traction force in the vertical direction for the second die, thereby demolding the die, and damage to the die and an internal metal ingot can be reduced due to the fact that the direction of the traction force is perpendicular to the surface of the die, and meanwhile, in order to ensure that the die can be kept in alignment with the traction block in the moving process of the bearing plate, a torsion spring is connected between the pry bar and the support frame, the utility model discloses a draw bar, including the draw bar, the draw bar is fixed, make the pinch bar be located the state of restriction groove one side, in order to carry out the fixed of position to the mould that needs the drawing of patterns, the opposite side that is located the support frame is equipped with the installation piece simultaneously, the installation piece is located same straight line with the draw piece, when first mould removes to the installation piece position, the tip of installation piece can slide into the guide way of first mould side, when the installation piece removes to the middle part position of first mould, the button head post of installation piece tip can be inconsistent with the second constant head tank on the first mould, thereby remind the current position of user, guarantee the draw bar of opposite side and be located the middle part position of mould simultaneously, can guarantee to provide fixed effect to first mould through the pinch bar drawing of patterns this moment, make the traction effect of draw piece bring better drawing of patterns function simultaneously.

(3) According to the hot melting casting equipment for processing the aluminum-zinc-strontium mixed plating material, the cleaning structure is connected between the casting structure and the support frame, and the bearing plate can be cleaned conveniently through the cleaning structure, namely: when the casting process is carried out for many times, a large amount of metal scraps possibly exist on the bearing plate to influence the flatness of the surface of the bearing plate, so that interference is formed to casting, in order to facilitate cleaning the bearing plate, the bearing plate can rotate at a certain angle with a connecting block at the bottom side, when a user drives the bottom side of the bearing plate to slide away from the middle position of the support frame through a motor, racks at the end part of the bearing plate can fall into support inclined grooves at the two sides of the support frame, the bearing plate is in an inclined state, so that the user can conveniently clean the metal scraps on the surface of the bearing plate in time, and after cleaning is finished, in order to reset the bearing plate, the user can rotate a rocker at the side of the support frame to drive a driving rod to rotate, gears at the two ends of the driving rod drive a lifting rod to lift through tooth grooves at the side of the lifting rod until a supporting wheel at the end part of the lifting rod collides with the bottom side of the racks and lifts the racks, simultaneously, along with the movement of the lifting rod, the end part of the inclined surface block at the inner side of the supporting frame is clamped with the locking groove at the side surface of the lifting rod, the rocker is released at the moment, the position of the lifting rod is fixed through the inclined surface block and the supporting plate is restored to a horizontal state at the moment, in the subsequent working process, when the supporting plate moves and the supporting plate moves to be in contact with the middle part of the supporting frame, the edge part of the supporting plate can be in contact with the end part of the extrusion rod at the moment, as the end part of the extrusion rod is in an inclined surface structure, along with the continuous movement of the supporting plate, the extrusion rod descends and pushes the inclined surface block to shrink until the lifting rod is released, the lifting rod descends again to retract to the inner side of the supporting frame under the dead weight of the lifting rod, the next time is facilitated to clean the supporting plate, meanwhile, the falling of the lifting rod is not influenced by the rocker through the ratchet block and the ratchet groove arranged between the rocker and the driving rod, convenient to use.

(4) The invention relates to a hot melting casting device for processing an aluminum-zinc-strontium mixed plating material, wherein the side surface of a support frame is provided with a support structure, and a worker can conveniently add metal materials to a melting furnace through the support structure, namely: because the feed port of smelting pot has certain height, for convenient operation, be located the support frame side and be equipped with the platen that can accomodate, the supporting shoe of bottom side and the connecting rod of side support simultaneously when the platen is expanded, guarantee that the platen has good stability, the security when promoting the workman and operating to be located the inboard of support frame and be equipped with the kicking block, when the user needs to expand the platen, release the platen back through the block of block tip of sliding the platen, the kicking block can be with the platen to the side ejecting, conveniently carry out the expansion of platen.

Drawings

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

FIG. 1 is a schematic diagram of the overall structure of a hot melt casting apparatus for processing aluminum-zinc-strontium mixed plating materials according to a preferred embodiment of the present invention;

FIG. 2 is a schematic view showing a connection structure of the supporting frame and the melting furnace shown in FIG. 1;

FIG. 3 is a schematic view of the furnace shown in FIG. 1;

FIG. 4 is a schematic view of the support frame shown in FIG. 1;

FIG. 5 is a schematic view of the connection structure of the support frame and the platen shown in FIG. 1;

FIG. 6 is an enlarged schematic view of the portion A shown in FIG. 5;

FIG. 7 is a schematic view of the connection structure of the platen and the connecting rod shown in FIG. 5;

FIG. 8 is a schematic view of the connection structure of the support bracket and the control rod shown in FIG. 1;

FIG. 9 is a schematic view of a connection structure of the support bracket and the pry bar shown in FIG. 1;

FIG. 10 is a schematic view of the connection of the pry bar and the pulling block shown in FIG. 9;

FIG. 11 is a schematic view of the connection of the support frame and lift bar shown in FIG. 2;

FIG. 12 is a schematic view of the connection of the support bracket and the wire rod shown in FIG. 2;

FIG. 13 is a schematic view of the connection between the lift pins and the carrier plate shown in FIG. 12;

fig. 14 is an enlarged schematic view of the B part shown in fig. 13;

FIG. 15 is a schematic view of the connection of the rocker and the drive rod shown in FIG. 11;

FIG. 16 is a schematic view of the extrusion stem of FIG. 14;

Fig. 17 is a schematic view of a connection structure of the support frame and the top block shown in fig. 7.

In the figure: 1. a support frame; 2. a melting furnace; 3. casting a structure; 301. a carrying plate; 302. a screw rod; 303. a first mold; 304. a second mold; 305. a motor; 306. a rack; 307. sector toothed plate; 308. a collision block; 309. a connecting block; 310. a spool; 311. an arc groove; 4. a positioning structure; 401. a control lever; 402. a blocking lever; 403. a first spring; 404. positioning columns; 405. a first positioning groove; 406. a mating groove; 5. a separation structure; 501. a pry bar; 502. a limiting groove; 503. a traction block; 504. a torsion spring; 505. a guide groove; 6. a support structure; 601. a platen; 602. a clamping block; 603. a connecting rod; 604. a second spring; 605. a support block; 606. a clamping groove; 607. a top block; 608. a third spring; 7. cleaning the structure; 701. a support chute; 702. a lifting rod; 703. a support wheel; 704. tooth slots; 705. a gear; 706. a driving rod; 707. a rocker; 708. an extrusion rod; 709. a bevel block; 710. a fourth spring; 711. a locking groove; 712. a ratchet groove; 713. a ratchet block; 714. a fifth spring; 8. a fixed structure; 801. a mounting block; 802. a knob post; 803. a sixth spring; 804. and a second positioning groove.

Detailed Description

The invention is further described in connection with the following detailed description in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the invention easy to understand.

As shown in fig. 1,2, 5, 8 and 9, the hot-melting casting device for processing aluminum-zinc-strontium mixed plating materials comprises a support frame 1, wherein a furnace 2 is arranged in the middle of the support frame 1, a casting structure 3 is connected between the furnace 2 and the support frame 1, a positioning structure 4 is arranged in the middle of the support frame 1, a separating structure 5 is arranged on one side of the support frame 1, a fixing structure 8 is arranged on the other side of the support frame 1, a cleaning structure 7 is connected between the casting structure 3 and the support frame 1, and a supporting structure 6 is arranged on the side surface of the support frame 1.

Specifically, as shown in fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 9, fig. 10, fig. 11, fig. 12, and fig. 14, the casting structure 3 includes a bearing plate 301, a middle part of the supporting frame 1 is slidably connected with the bearing plate 301, an end part of the bearing plate 301 is fixedly connected with a rack 306, the furnace 2 is rotatably connected with the supporting frame 1, two sides of the furnace 2 are fixedly connected with a sector toothed plate 307, the rack 306 is meshed with the sector toothed plate 307, a connecting block 309 is disposed at a bottom side of the bearing plate 301, a screw rod 302 is screwed at a middle part of the connecting block 309, the screw rod 302 is rotatably connected with the supporting frame 1, a first mold 303 and a second mold 304 are disposed on the bearing plate 301, an end part of the supporting frame 1 is mounted with a motor 305, an end part of the motor 305 is fixedly connected with the screw rod 302 through a coupling 303, an end part of the bearing plate 301 is fixedly connected with a collision block 308 between the first mold 303 and the second mold 304, the collision block 308 is meshed with the sector toothed plate 307, a sector toothed plate 307 is connected with a sector toothed plate 310, and a sliding arc 310 is connected with a sliding arc 310 of the side of the supporting frame 1 through a sliding arc 310; the safety risk of workers in the process of casting a metal ingot can be reduced by the casting structure 3, namely: firstly, the motor 305 at the end of the supporting frame 1 is electrically connected with an external power supply, the screw rod 302 can be driven to rotate by the power supply, then the bearing plate 301 is driven to slide in the middle of the supporting frame 1, the middle position of the bearing plate 301 is used for placing the first die 303 and the second die 304, the first die 303 and the second die 304 are spliced together to fix a metal ingot, after the end of the complete die is abutted against the abutting block 308 at the end of the bearing plate 301, the motor 305 can be started to drive the bearing plate 301 to move towards the melting furnace 2 through the connecting block 309, the molten plated metal in the melting furnace 2 is in a molten state, along with the movement of the bearing plate 301, the rack 306 at the end of the bearing plate 301 is meshed with the fan-shaped toothed plate 307 at the side surface of the melting furnace 2, so as to drive the melting furnace 2 to start to rotate, when the melting furnace 2 is poured, the dies are moved to the vicinity of the mouth of the melting furnace 2 to receive molten metal until the melting furnace 2 is reset by the motor 305 after pouring, the molten metal is prevented from being directly approaching the melting furnace 2, the production safety is improved, and the melting furnace 2 filled with molten metal is rotated to the position of the melting furnace 2, so that the molten metal is more controllable to be poured to the inner side of the melting plate 307, and simultaneously, the inner side of the melting plate 307 is placed in the inner side of the melting furnace 2 is limited in a stable state, and the stable arc is formed, and the stable state.

Specifically, as shown in fig. 1, fig. 6, and fig. 8, the positioning structure 4 includes a blocking rod 402, the inner side of the support frame 1 is provided with the blocking rod 402, the side surfaces of the first mold 303 and the second mold 304 are respectively provided with a matching groove 406, the first mold 303 and the second mold 304 are respectively connected with the end part of the blocking rod 402 provided on the same side in a sliding manner through the matching grooves 406, the side surfaces of the first mold 303 and the second mold 304 are in contact with the support frame 1, the end part of the blocking rod 402 is connected with a control rod 401 in a sliding manner, a first spring 403 is fixedly connected between the control rod 401 and the blocking rod 402, the side surface of the control rod 401 is fixedly connected with a positioning column 404, the inner side of the support frame 1 is provided with a plurality of first positioning grooves 405, and the positioning column 404 is engaged with the support frame 1 through the first positioning grooves 405; the receiving position of the die can be adjusted through the positioning structure 4, so that the casting is ensured to be performed correctly, namely: under the condition that the amount of molten metal in the melting furnace 2 is different, the rotation angle of the melting furnace 2 needs to be correspondingly adjusted when pouring is performed, at this time, in order to enable the die to correctly receive the molten metal, a user can adjust the final stop position of the die through the control rod 401 arranged on the side face of the supporting frame 1, the control rod 401 on any side is pressed, the positioning column 404 at the end part of the control rod 401 can be separated from the first positioning groove 405 on the inner side of the supporting frame 1, at this time, the control rod 401 is released after being slid to a proper position, and under the pushing of the first spring 403, the positioning column 404 is clamped with the corresponding first positioning groove 405 again, so that the position of the current blocking rod 402 is fixed, the side faces of the first die 303 and the second die 304 are respectively provided with the matching grooves 406, when the die moves to the position of the blocking rod 402 along with the bearing plate 301, the end part of the blocking rod 402 can slide into the matching grooves 406 until the blocking the die is in a collision, at this time, the bearing plate 301 can drive the rotation of the melting furnace 2 continuously, and thus the accuracy of the final stop position adjustment of the die can be ensured by adjusting the position of the blocking rod 402.

Specifically, as shown in fig. 1, 9, 10 and 11, the separation structure 5 includes a pry bar 501, a pry bar 501 is rotatably connected to a side surface of the support frame 1, a torsion spring 504 is fixedly connected between the pry bar 501 and the support frame 1, a limiting groove 502 is formed in the middle of the pry bar 501, a traction block 503 is slidably connected to the pry bar 501 through the limiting groove 502, an end portion of the traction block 503 is vertically arranged with the support frame 1, the traction block 503 is slidably connected with the support frame 1, and guide grooves 505 are formed in side surfaces of the first mold 303 and the second mold 304; the cooled mould can be separated by the separating structure 5, and damage to the mould or the workpiece is reduced, namely: after casting of the mold is completed, the bearing plate 301 is moved reversely by the motor 305, at this time, the rack 306 at the end of the bearing plate 301 drives the melting furnace 2 to reset, then a user can continue to drive the bearing plate 301 to move until the end of the traction block 503 at the inner side of the support frame 1 slides into the guide groove 505 at the side of the second mold 304, at this time, after the user fixes the first mold 303 at the other side, the user only needs to strike the pry bar 501 to the outside, so that the middle part of the pry bar 501 pulls the traction block 503, and can provide traction force in the vertical direction for the second mold 304, thereby demolding is performed on the mold, and damage to the mold and an internal metal ingot can be reduced due to the fact that the direction of the traction force is perpendicular to the surface of the mold, meanwhile, in order to ensure that the mold can maintain an aligned state with the traction block 503 in the moving process of the bearing plate 301, a torsion spring 504 is connected between the pry bar 501 and the support frame 1, and the state that the end of the traction block 503 is located at one side of the limiting groove under the static state.

Specifically, as shown in fig. 9, the fixing structure 8 includes a mounting block 801, the inner side of the support frame 1 is vertically and fixedly connected with the mounting block 801, the mounting block 801 and the traction block 503 are disposed on the same straight line, an end portion of the mounting block 801 is slidably connected with a round head column 802, a sixth spring 803 is fixedly connected between the round head column 802 and the mounting block 801, and a second positioning groove 804 is formed in a side surface of the first mold 303; the mould that needs the drawing of patterns can be fixed a position through fixed knot constructs 8, namely: in order to fix the mould that needs the drawing of patterns carries out the position, fix the first mould 303 of opposite side simultaneously, the opposite side that is located support frame 1 is equipped with installation piece 801, installation piece 801 is located same straight line with traction block 503, when first mould 303 removes to installation piece 801 position, the tip of installation piece 801 can slide into in the guide way 505 of first mould 303 side, when installation piece 801 removes to the middle part position of first mould 303, the button head post 802 of installation piece 801 tip can be inconsistent with the second constant head tank 804 on first mould 303, thereby remind the current position of user, guarantee the traction lever of opposite side is located the middle part position of mould simultaneously, carry out the drawing of patterns through crow bar 501 at this moment can guarantee to provide fixed effect to first mould 303, make the traction effect of traction block 503 bring better drawing of patterns function simultaneously.

Specifically, as shown in fig. 2, 11, 12, 13, 14, 15, and 16, the cleaning structure 7 includes a supporting chute 701, two sides of the supporting frame 1 are respectively provided with the supporting chute 701, the supporting plate 301 is rotationally connected with the connecting block 309, the bottom side of the supporting plate 301 is slidingly connected with the supporting frame 1, the inner side of the supporting frame 1 is slidingly connected with a lifting rod 702, an end of the lifting rod 702 is rotationally connected with a supporting wheel 703, the supporting wheel 703 is abutted against the bottom side of the supporting plate 301, a locking groove 711 is provided on a side surface of the lifting rod 702, the inner side of the supporting frame 1 is connected with a bevel block 709 in a sliding way, a fourth spring 710 is fixedly connected between the bevel block 709 and the supporting frame 1, the bevel side of the bevel block 709 is abutted against a squeezing rod 708, the end part of the squeezing rod 708 is in a bevel structure, the end part of the squeezing rod 708 is abutted against the bottom side of the bearing plate 301, a tooth slot 704 is arranged on the side surface of the lifting rod 702, a driving rod 706 is rotatably connected on the inner side of the supporting frame 1, two ends of the driving rod 706 are respectively fixedly connected with a gear 705, the gears 705 are meshed with the lifting rod 702 through the tooth slot 704, the end part of the driving rod 706 is rotatably connected with a rocker 707, a ratchet groove is formed in the inner side of the rocker 707, a ratchet block 713 is slidably connected to the side surface of the driving rod 706, a fifth spring 714 is fixedly connected between the ratchet block 713 and the driving rod 706, and the ratchet block 713 is meshed with the rocker 707 through the ratchet groove; the carrying plate 301 can be cleaned conveniently by the cleaning structure 7, namely: when a plurality of casting processes are performed, a large amount of metal scraps may exist on the bearing plate 301 to affect the flatness of the surface of the bearing plate 301, so that interference is formed to casting, in order to facilitate cleaning of the bearing plate 301, the bearing plate 301 may rotate at a certain angle with the connection block 309 at the bottom side, when a user drives the bottom side of the bearing plate 301 to slide away from the middle position of the support frame 1 through the motor 305, the racks 306 at the end of the bearing plate 301 fall into the support chute 701 at two sides of the support frame 1, and at this time, the bearing plate 301 is in an inclined state, the metal scraps on the surface of the bearing plate 301 can be cleaned in time conveniently, after cleaning, in order to reset the bearing plate 301, a user can rotate the rocker 707 on the side surface of the support frame 1 to drive the driving rod 706 to rotate, the gears 705 on the two ends of the driving rod 706 drive the lifting rod 702 to ascend through the tooth grooves 704 on the side surface of the lifting rod 702 until the supporting wheels 703 on the end part of the lifting rod 702 are abutted against the bottom side of the rack 306 and lift the rack 306, simultaneously with the movement of the lifting rod 702, the end parts of the bevel blocks 709 on the inner side of the support frame 1 are clamped with the locking grooves 711 on the side surface of the lifting rod 702, at this time, the rocker 707 is released, the position of the lifting lever 702 is fixed by the inclined block 709 and the carrying plate 301 is restored to the horizontal state, in the subsequent working process, when the carrying plate 301 moves and the carrying plate 301 moves to collide with the middle part of the supporting frame 1, the edge part of the carrying plate 301 collides with the end part of the extrusion lever 708, because the end part of the extrusion lever 708 is in an inclined structure, the extrusion lever 708 descends and pushes the inclined block 709 to shrink as the carrying plate 301 moves continuously, until the lifting lever 702 is released, the lifting lever 702 descends again to retract to the inner side of the supporting frame 1 under the dead weight of the lifting stem, the next cleaning of the bearing plate 301 is facilitated, and meanwhile, the falling-back of the lifting rod 702 is not influenced by the rocker 707 through the ratchet block 713 and the ratchet groove arranged between the rocker 707 and the driving rod 706, so that the lifting rod is convenient to use.

Specifically, as shown in fig. 1, 5, 7 and 17, the supporting structure 6 includes a platen 601, a side surface of the supporting frame 1 is rotatably connected with the platen 601, an end portion of the platen 601 is slidably connected with a clamping block 602, a second spring 604 is fixedly connected between the clamping block 602 and the platen 601, a clamping groove 606 is provided on a side surface of the supporting frame 1, a connecting rod 603 is provided between the platen 601 and the supporting frame 1, the connecting rod 603 is rotatably connected with the supporting frame 1, the connecting rod 603 is slidably connected with the platen 601, a side surface of the supporting frame 1 is fixedly connected with a supporting block 605, the supporting block 605 is in contact with a bottom side of the platen 601, a top block 607 is slidably connected with a side surface of the supporting frame 1, and a third spring 608 is fixedly connected between the top block 607 and the supporting frame 1; the addition of the metal material to the furnace 2 by the worker is facilitated by the support structure 6, namely: because the feed port of smelting pot 2 has certain height, for convenient operation, be located the platen 601 that support frame 1 side was equipped with and can accomodate, support through supporting shoe 605 of bottom side and the connecting rod 603 of side simultaneously when platen 601 expands, guarantee that platen 601 has good stability, the security when promoting the workman and operate to be located the inboard of support frame 1 and be equipped with kicking block 607, when the user needs to expand platen 601, release platen 601 through the block 602 of sliding platen 601 tip after, kicking block 607 can be with platen 601 to the side ejecting, conveniently carry out the expansion of platen 601.

When the invention is used, firstly, the motor 305 at the end part of the support frame 1 is electrically connected with an external power supply, the screw rod 302 can be driven to rotate by the power supply, then the bearing plate 301 is driven to slide in the middle part of the support frame 1, the middle part of the bearing plate 301 is used for placing the first die 303 and the second die 304, the first die 303 and the second die 304 are spliced together to shape a metal ingot, after the end part of the complete die is abutted against the abutting block 308 at the end part of the bearing plate 301, the motor 305 is started, the bearing plate 301 can be driven to move towards the melting furnace 2 by the connecting block 309, and the melting furnace 2 is internally provided with molten metal plating materials, with the movement of the bearing plate 301, the racks 306 at the end of the bearing plate 301 are meshed with the sector toothed plates 307 at the side of the melting furnace 2, so that the melting furnace 2 is driven to rotate, when the melting furnace 2 is toppled over, the die moves to the vicinity of the mouth of the melting furnace 2 to receive molten metal until the melting furnace 2 is reset by the motor 305 after pouring is completed, the direct approach of workers to the melting furnace 2 for toppling molten metal is avoided, the production safety is improved, and for the melting furnace 2 filled with molten metal, the rotating position of the melting furnace 2 is close to the pouring mouth, so that the toppling of molten metal is more controllable, meanwhile, the slide posts 310 arranged at the side of the sector toothed plates 307 slide in the arc grooves 311 at the inner side of the supporting frame 1, the rotation of the melting furnace 2 is limited, the stability of the melting furnace 2 in a static state is improved, under the condition that the quantity of molten metal in the melting furnace 2 is different, the rotation angle of the melting furnace 2 needs to be correspondingly adjusted when pouring is carried out, at the moment, in order to enable the mold to correctly receive the molten metal, a user can adjust the final stop position of the mold through the control rod 401 arranged on the side surface of the support frame 1, the positioning column 404 at the end part of the control rod 401 can be separated from the first positioning groove 405 on the inner side of the support frame 1 by pressing the control rod 401 on any side, at the moment, the control rod 401 is released after being slid to a proper position, under the pushing of the first spring 403, the positioning column 404 is clamped with the corresponding first positioning groove 405 again, so that the position of the current blocking rod 402 is fixed, the side surfaces of the first die 303 and the second die 304 are provided with the matching groove 406, when the dies move to the position of the blocking rod 402 along with the bearing plate 301, the end parts of the blocking rod 402 slide into the matching groove 406 until the dies are abutted, so that the dies are blocked from moving continuously, the bearing plate 301 can drive the rotation of the melting furnace 2 to move continuously, thus, the final stop position of the dies can be adjusted by adjusting the position of the blocking rod 402, the casting accuracy is ensured, after casting of the mold is completed, the bearing plate 301 is moved reversely by the motor 305, at this time, the rack 306 at the end of the bearing plate 301 drives the melting furnace 2 to reset, then the user can continue to drive the bearing plate 301 to move until the end of the traction block 503 at the inner side of the support frame 1 slides into the guide groove 505 at the side of the second mold 304, at this time, after the user fixes the first mold 303 at the other side, the user only needs to strike the pry bar 501 to the outside, so that the middle part of the pry bar 501 pulls the traction block 503, and then the traction force in the vertical direction can be provided for the second mold 304, thereby demolding the mold, because the direction of the traction force is perpendicular to the surface of the die, the damage to the die and the internal metal ingot can be reduced, meanwhile, in order to ensure that the die can be aligned with the traction block 503 in the moving process of the bearing plate 301, a torsion spring 504 is connected between the pry bar 501 and the support frame 1, so that the pry bar 501 keeps the end part of the traction block 503 positioned at one side of the limiting groove 502 in a static state, in order to fix the position of the die to be demolded, the first die 303 at the other side is fixed, the mounting block 801 is arranged at the other side of the support frame 1, the mounting block 801 and the traction block 503 are positioned on the same straight line, when the first mold 303 moves to the position of the mounting block 801, the end of the mounting block 801 slides into the guide groove 505 on the side surface of the first mold 303, when the mounting block 801 moves to the middle position of the first mold 303, the round head column 802 on the end of the mounting block 801 collides with the second positioning groove 804 on the first mold 303, thereby reminding a user of the current position, ensuring that the traction rod on the other side is simultaneously positioned at the middle position of the mold, at the moment, demolding through the prying bar 501 can ensure that a fixing effect is provided for the first mold 303, simultaneously ensuring that the traction effect of the traction block 503 brings a better demolding function, when the casting process is performed for many times, a large amount of metal scraps may exist on the bearing plate 301 to affect the flatness of the surface of the bearing plate 301, so that interference is formed to casting, in order to facilitate cleaning of the bearing plate 301, the bearing plate 301 itself may rotate at a certain angle with the connection block 309 at the bottom side, when a user drives the bottom side of the bearing plate 301 to slide away from the middle position of the support frame 1 through the motor 305, the racks 306 at the end of the bearing plate 301 may fall into the support chute 701 at two sides of the support frame 1, at this time, the bearing plate 301 is in an inclined state, so that the user can clean the metal scraps on the surface of the bearing plate 301 in time, after cleaning, in order to reset the carrying plate 301, the user may rotate the rocker 707 located on the side of the supporting frame 1 to drive the driving rod 706 to rotate, the gears 705 at two ends of the driving rod 706 drive the lifting rod 702 to lift up through the tooth grooves 704 on the side of the lifting rod 702 until the supporting wheel 703 at the end of the lifting rod 702 abuts against the bottom side of the rack 306 and lifts the rack 306, meanwhile, along with the movement of the lifting rod 702, the end of the inclined surface block 709 at the inner side of the supporting frame 1 is engaged with the locking groove 711 on the side of the lifting rod 702, at this time, the rocker 707 is released, at this time, the position of the lifting rod 702 is fixed through the inclined surface block 709 and the carrying plate 301 is restored to the horizontal state, in the subsequent working process, when the bearing plate 301 moves and the bearing plate 301 moves to collide with the middle part of the supporting frame 1, at this time, the edge part of the bearing plate 301 collides with the end part of the extrusion rod 708, because the end part of the extrusion rod 708 is in an inclined surface structure, the extrusion rod 708 descends and pushes the inclined surface block 709 to shrink along with the continuous movement of the bearing plate 301 until the lifting rod 702 is released, under the dead weight of the lifting rod, the lifting rod 702 descends again and retracts to the inner side of the supporting frame 1, the next cleaning of the bearing plate 301 is facilitated, meanwhile, the falling of the lifting rod 702 is not influenced by the rocking rod 707 through the ratchet block 713 and the ratchet groove arranged between the rocking rod 707 and the driving rod 706, the convenient to use, because the feed inlet of smelting pot 2 has certain height, for convenient operation, be located the platen 601 that can accomodate that is equipped with in support frame 1 side, support through the supporting shoe 605 of bottom side and the connecting rod 603 of side simultaneously when platen 601 expands, guarantee that platen 601 has good stability, the security when promoting the workman and operate, and be located the inboard of support frame 1 and be equipped with kicking block 607, when the user needs to expand platen 601, release platen 601 through the block 602 of slip platen 601 tip after, kicking block 607 can be with platen 601 to the side ejecting, conveniently carry out the expansion of platen 601.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (10)

1. The hot melting casting device for processing the aluminum-zinc-strontium mixed plating material is characterized by comprising a support frame (1), wherein a smelting furnace (2) is arranged in the middle of the support frame (1), a casting structure (3) is connected between the smelting furnace (2) and the support frame (1), a positioning structure (4) is arranged in the middle of the support frame (1), a separating structure (5) is arranged on one side of the support frame (1), a fixing structure (8) is arranged on the other side of the support frame (1), a cleaning structure (7) is connected between the casting structure (3) and the support frame (1), and a supporting structure (6) is arranged on the side face of the support frame (1);

Casting structure (3) are including loading board (301), the middle part sliding connection of support frame (1) has loading board (301), the tip fixedly connected with rack (306) of loading board (301), rotate between smelting pot (2) and support frame (1) and be connected, the both sides fixedly connected with fan-shaped pinion rack (307) of smelting pot (2), mesh between rack (306) and fan-shaped pinion rack (307), the bottom side of loading board (301) is equipped with connecting block (309), the middle part threaded connection of connecting block (309) has lead screw (302), rotate between lead screw (302) and support frame (1) and be connected, be equipped with first mould (303) and second mould (304) on loading board (301).

2. The hot-melt casting apparatus for processing an aluminum-zinc-strontium mixed plating material according to claim 1, wherein: the end part of the support frame (1) is provided with a motor (305), the end part of the motor (305) is fixedly connected with a screw rod (302) through a coupler, a first die (303) and a second die (304) are in interference, the end part of the bearing plate (301) is fixedly connected with an interference block (308), the interference block (308) is in interference with the first die (303) and the second die (304), an arc groove (311) is formed in the side surface of the support frame (1), a sliding column (310) is fixedly connected with the side surface of the sector toothed plate (307), and the sliding column (310) is in sliding connection with the support frame (1) through the arc groove (311).

3. The hot-melt casting apparatus for processing an aluminum-zinc-strontium mixed plating material according to claim 1, wherein: the positioning structure (4) comprises a blocking rod (402), the blocking rod (402) is arranged on the inner side of the supporting frame (1), the side faces of the first die (303) and the second die (304) are respectively provided with a matching groove (406), the first die (303) and the second die (304) are respectively connected with the end part of the blocking rod (402) arranged on the same side through the matching grooves (406) in a sliding mode, and the side faces of the first die (303) and the second die (304) are in contact with the supporting frame (1).

4. A hot melt casting apparatus for processing an aluminum zinc strontium mixed plating material according to claim 3, wherein: the end sliding connection who blocks pole (402) has control rod (401), fixedly connected with first spring (403) between control rod (401) and the stop rod (402), sliding connection between control rod (401) and support frame (1), the side fixedly connected with reference column (404) of control rod (401), a plurality of first constant head tanks (405) have been seted up to the inboard of support frame (1), reference column (404) are through first constant head tank (405) and support frame (1) looks block.

5. The hot-melt casting apparatus for processing an aluminum-zinc-strontium mixed plating material according to claim 1, wherein: separation structure (5) are including pinch bar (501), the side of support frame (1) rotates and is connected with pinch bar (501), fixedly connected with torsional spring (504) between pinch bar (501) and support frame (1), restriction groove (502) have been seted up at the middle part of pinch bar (501), pinch bar (501) have traction block (503) through restriction groove (502) sliding connection, the tip of traction block (503) sets up perpendicularly with support frame (1), just sliding connection between traction block (503) and support frame (1), guide way (505) have all been seted up to the side of first mould (303) and second mould (304).

6. The hot-melt casting apparatus for processing aluminum-zinc-strontium mixed plating material according to claim 5, wherein: the fixing structure (8) comprises a mounting block (801), the mounting block (801) is vertically and fixedly connected with the inner side of the supporting frame (1), the mounting block (801) and the traction block (503) are arranged on the same straight line, the end part of the mounting block (801) is slidably connected with a round head column (802), a sixth spring (803) is fixedly connected between the round head column (802) and the mounting block (801), and a second positioning groove (804) is formed in the side face of the first die (303).

7. The hot-melt casting apparatus for processing an aluminum-zinc-strontium mixed plating material according to claim 1, wherein: the cleaning structure (7) comprises supporting inclined grooves (701), the supporting inclined grooves (701) are respectively formed in two sides of the supporting frame (1), the supporting plate (301) is connected with the connecting block (309) in a rotating mode, the bottom side of the supporting plate (301) is connected with the supporting frame (1) in a sliding mode, the lifting rod (702) is connected with the inner side of the supporting frame (1) in a sliding mode, the end portion of the lifting rod (702) is connected with the supporting wheel (703) in a rotating mode, the supporting wheel (703) is abutted to the bottom side of the supporting plate (301), locking grooves (711) are formed in the side face of the lifting rod (702), a slope block (709) is connected with the inner side of the supporting frame (1) in a sliding mode, a fourth spring (710) is fixedly connected between the slope block (709) and the supporting frame (1), the inclined side face of the slope block (709) is abutted to the pressing rod (708), and the end portion of the pressing rod (708) is of a slope structure, and the end portion of the pressing rod (708) is abutted to the bottom side of the supporting plate (301).

8. The hot-melt casting apparatus for processing aluminum-zinc-strontium mixed plating material according to claim 7, wherein: tooth grooves (704) are formed in the side faces of the lifting rods (702), driving rods (706) are rotatably connected to the inner sides of the supporting frames (1), two ends of each driving rod (706) are fixedly connected with gears (705) respectively, the gears (705) are meshed with the lifting rods (702) through the tooth grooves (704), rocking bars (707) are rotatably connected to the end portions of the driving rods (706), ratchet grooves (712) are formed in the inner sides of the rocking bars (707), ratchet blocks (713) are slidably connected to the side faces of the driving rods (706), fifth springs (714) are fixedly connected between the ratchet blocks (713) and the driving rods (706), and the ratchet blocks (713) are meshed with the rocking bars (707) through the ratchet grooves (712).

9. The hot-melt casting apparatus for processing an aluminum-zinc-strontium mixed plating material according to claim 1, wherein: the supporting structure (6) comprises a table plate (601), the table plate (601) is rotationally connected to the side face of the supporting frame (1), a clamping block (602) is slidably connected to the end portion of the table plate (601), a second spring (604) is fixedly connected between the clamping block (602) and the table plate (601), a clamping groove (606) is formed in the side face of the supporting frame (1), a connecting rod (603) is arranged between the table plate (601) and the supporting frame (1), the connecting rod (603) is rotationally connected with the supporting frame (1), and the connecting rod (603) is slidably connected with the table plate (601).

10. The hot-melt casting apparatus for processing an aluminum-zinc-strontium mixed plating material according to claim 9, wherein: the side fixedly connected with supporting shoe (605) of support frame (1), supporting shoe (605) are inconsistent with the bottom side of platen (601), the side sliding connection of support frame (1) has kicking block (607), fixedly connected with third spring (608) between kicking block (607) and support frame (1).