CN115041661A

CN115041661A - Zinc alloy plate production equipment integrating forming and stacking

Info

Publication number: CN115041661A
Application number: CN202210833064.4A
Authority: CN
Inventors: 陈文渊; 徐特; 邹本东; 奚君华; 张佳兵; 何专; 张鹏
Original assignee: Jiangxi Prosperity Metal Co ltd
Current assignee: Jiangxi Prosperity Metal Co ltd
Priority date: 2022-07-14
Filing date: 2022-07-14
Publication date: 2022-09-13
Anticipated expiration: 2042-07-14
Also published as: CN115041661B

Abstract

The invention relates to zinc alloy plate production equipment, in particular to zinc alloy plate production equipment integrating molding and stacking. The invention provides a forming and stacking integrated zinc alloy plate production device with higher production efficiency. A zinc alloy plate production device integrating molding and stacking comprises a molding die frame, a first fixer, a second fixer and the like; the upper side of the rear part of the forming die frame is connected with two first fixers, the front side and the rear side in the forming die frame are both connected with partition plates, and the two first fixers are connected with second fixers in a rotating mode. According to the invention, liquid zinc alloy is injected among the partition plate, the forming die frame and the upper die cover through the injection port, so that three formed zinc alloy plates are stacked together, thus the forming and stacking effect is realized, and the production efficiency is higher.

Description

Zinc alloy plate production equipment integrating forming and stacking

Technical Field

The invention relates to zinc alloy plate production equipment, in particular to zinc alloy plate production equipment integrating molding and stacking.

Background

The zinc alloy is an alloy composed of zinc as a basic element, and because the corrosion resistance and the mechanical property of the zinc alloy are good, people often die-cast the zinc alloy into a zinc alloy plate by an injection molding method, and people often die-cast the zinc alloy by production equipment, but the existing production equipment has the following problems during production: when the zinc alloy plate is produced, only one zinc alloy plate can be produced by one die, so that the production efficiency is low, and the use requirements of people are difficult to meet, therefore, a production device needs to be designed.

The forming and stacking integrated zinc alloy plate production equipment with high production efficiency is designed to overcome the defect that the existing production equipment is low in efficiency when producing the zinc alloy plate.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides the forming and stacking integrated zinc alloy plate production equipment with higher production efficiency, so as to overcome the defect of low efficiency of the existing production equipment in the production of zinc alloy plates.

In order to achieve the above purpose, the invention is realized by the following scheme: a zinc alloy plate production device integrating forming and stacking comprises a forming die frame, an upper die cover, a partition plate, first fixers, second fixers and first torsion springs, wherein the upper side of the rear part of the forming die frame is connected with the two first fixers, the front side and the rear side in the forming die frame are both connected with the partition plate, the two first fixers are both rotatably connected with the second fixers, the first torsion springs are connected between the left side and the right side of the second fixer on the left side and the left side of the first fixer on the left side, the first torsion springs are connected between the left side and the right side of the second fixer on the right side and the first fixer on the right side, the first torsion springs are wound on the second fixers, the upper die cover is connected between the two second fixers, the left side and the right side of the top of the upper die cover are both provided with injection molding openings, the zinc alloy plate production device is characterized by further comprising a reinforcing mechanism and a cooling forming mechanism, the reinforcing mechanism is arranged on the forming die frame, the forming die frame is reinforced through the movement of the reinforcing mechanism, the forming die frame is prevented from deforming due to thermal expansion, the cooling forming mechanism is arranged on the forming die frame, and the liquid zinc alloy is cooled through the cooling forming mechanism.

As the improvement of above-mentioned scheme, strengthening mechanism is including the rolling disc, second torsion spring, the pole that links up, reinforcement ware and gag lever post, the middle rotary type in forming die frame rear portion is connected with the rolling disc, be connected with second torsion spring between rolling disc and the forming die frame, second torsion spring is around the rolling disc front side, the equal rotary type in rolling disc left and right sides is connected with the pole that links up, the middle gag lever post that all is connected with in rolling disc left and right sides, it is used for the reinforcement ware to forming die frame to all be connected with to the slidingtype on two gag lever posts, left reinforcement ware is connected with left pole rotary type that links up, the reinforcement ware on right side is connected with the pole rotary type that links up on right side.

As the improvement of above-mentioned scheme, cooling forming mechanism is including the drain pipe, the liquid reserve tank, restriction board and extension spring, the drain pipe has all been around to the forming die frame left and right sides, the forming die frame is all passed to both sides around the drain pipe, two drain pipe upper portions all communicate the liquid reserve tank that is used for the splendid attire refrigerant, two liquid reserve tank bottom rear sides all are connected with extension spring, two drain pipe rear sides all slidingtype connection have the restriction board, left extension spring is connected with left restriction board, the extension spring on right side is connected with the restriction board on right side, it has the circulation mouth all to open on two restriction boards.

As the improvement of the scheme, the improved mould cover locking device comprises a locking mechanism used for clamping the upper mould cover, wherein the locking mechanism comprises a clamping lock, a limiting stopper, a first fixed shaft and a first compression spring, the clamping lock is connected to the upper side of the front part of the upper mould cover, the two first fixed shafts are connected to the front side in the forming mould frame, the limiting stoppers are connected to the two first fixed shafts in a sliding mode, the first compression spring is connected between the two limiting stoppers and the forming mould frame, and the first compression spring is wound on the first fixed shaft.

The improvement as above-mentioned scheme, still including the mould apron anti-expansion mechanism who is used for pushing down the upper die cover, mould apron anti-expansion mechanism is including the catch bar, the carriage, the fixed plate, second compression spring and lower catch bar, two reinforcement ware front sides all are connected with the catch bar, the anterior left and right sides of forming die frame all is connected with the fixed plate, it is connected with the carriage all to slidingly on two fixed plates, left catch bar and left carriage slidingly are connected, catch bar and the carriage slidingly on right side are connected, be connected with second compression spring between left carriage and the left fixed plate, be connected with second compression spring between carriage on right side and the fixed plate on right side, second compression spring is around the carriage rear side, two carriage upside all slidingly are connected with the depression bar down.

As the improvement of above-mentioned scheme, still including being used for realizing automatically cooling's circulation of liquid opening mechanism, circulation of liquid opening mechanism is including linking up the frame, first revolving rack, second fixed axle and third fixed axle, two carriage downside all are connected with linking up the frame, the anterior left and right sides of forming die frame all is connected with the second fixed axle, equal rotary type is connected with first revolving rack on two second fixed axles, left first revolving rack is connected with left linking frame rotary type, the first revolving rack on right side is connected with linking frame rotary type on right side, two anterior downside of limiting plate all are connected with the third fixed axle, all open the spout on two first revolving racks, left third fixed axle and left spout sliding connection, the third fixed axle on right side and the spout sliding connection on right side.

As the improvement of the scheme, the device further comprises a limiting mechanism used for clamping the rotating disc, the limiting mechanism comprises a second rotating frame, a clamping pin and a third compression spring, the second rotating frame is connected onto the rotating disc, the clamping pin is connected to the upper side of the second rotating frame in a sliding mode, the third compression spring is connected between the clamping pin and the second rotating frame and wound on the rear side of the clamping pin, and the clamping groove is formed in the rear portion of the forming die frame.

As an improvement of the scheme, the lower pressing rod is made of damping materials.

The invention has the advantages that: 1. according to the invention, liquid zinc alloy is injected among the partition plate, the forming die frame and the upper die cover through the injection port by people, so that three formed zinc alloy plates are stacked together, thus the forming and stacking effect is realized, and the production efficiency is higher;

2. the connecting frame moves downwards to drive the first rotating frame to rotate, so that the third fixed shaft and the limiting plate move upwards, the circulation port moves upwards, and then the refrigerant flows backwards through the liquid outlet pipe, so that the automatic cooling effect is realized;

3. the second rotating frame is driven to rotate through rotation of the rotating disc, so that the clamping pins rotate, when the clamping pins rotate to be in contact with the clamping grooves, the third compression springs reset to drive the clamping pins to move forwards into the clamping grooves, and therefore the clamping effect is achieved.

Drawings

Fig. 1 is a schematic perspective view of a first part of the present invention.

Fig. 2 is a schematic perspective view of a second part of the present invention.

Fig. 3 is a partial perspective view of the present invention.

Fig. 4 is a schematic perspective view of a first embodiment of the reinforcement mechanism of the present invention.

Fig. 5 is a schematic perspective view of a second embodiment of the reinforcement mechanism of the present invention.

Fig. 6 is a schematic perspective view of a first cooling and forming mechanism according to the present invention.

Fig. 7 is a schematic perspective view of a second cooling and forming mechanism of the present invention.

Fig. 8 is a schematic perspective view of a third cooling and forming mechanism of the present invention.

Fig. 9 is a schematic perspective view of a first locking mechanism of the present invention.

Fig. 10 is a schematic perspective view of a second locking mechanism of the present invention.

Fig. 11 is a schematic perspective view of a first structure of the mold cover expansion preventing mechanism of the present invention.

Fig. 12 is a schematic perspective view of a second structure of the mold cover expansion preventing mechanism of the present invention.

Fig. 13 is a first perspective view of the opening mechanism for opening liquid flow according to the present invention.

Fig. 14 is a schematic perspective view of a second embodiment of the opening mechanism for opening fluid communication according to the present invention.

Fig. 15 is a schematic perspective view of the limiting mechanism of the present invention.

Wherein the figures include the following reference numerals: 1_ molding die holder, 2_ upper die cover, 21_ injection port, 22_ partition plate, 3_ first holder, 4_ second holder, 5_ first torsion spring, 6_ reinforcement mechanism, 61_ rotating disk, 62_ second torsion spring, 63_ engagement rod, 64_ reinforcement mechanism, 65_ stopper rod, 7_ cooling molding mechanism, 71_ liquid outlet tube, 72_ liquid storage tank, 73_ stopper plate, 74_ extension spring, 75_ circulation port, 8_ locking mechanism, 81_ latch, 82_ stopper, 83_ first fixed shaft, 84_ first compression spring, 9_ die cover plate expansion prevention mechanism, 91_ push rod, 92_ carriage, 93_ fixed plate, 94_ second compression spring, 95_ lower press rod, 10_ liquid circulation opening mechanism, 101_ holder, 102_ first rotating engagement holder, 103_ second slide, 104_ slide, 105_ third fixed shaft, 11_ stopper mechanism, 111_ second turret, 112_ bayonet, 113_ third compression spring, 114_ bayonet.

Detailed Description

The invention will be further described with reference to the accompanying drawings and the detailed description below:

example 1

A zinc alloy plate production device integrating forming and stacking is disclosed, referring to figures 1-3, comprising a forming die frame 1, an upper die cover 2, an injection molding opening 21, a partition plate 22, first fixers 3, second fixers 4, first torsion springs 5, a reinforcing mechanism 6 and a cooling forming mechanism 7, wherein the upper side of the rear part of the forming die frame 1 is connected with two first fixers 3, the partition plate 22 is welded on the front side and the rear side in the forming die frame 1, the two first fixers 3 are respectively connected with the second fixers 4 in a rotating mode, the first torsion springs 5 are respectively connected between the left side and the right side of the second fixer 4 on the left side and the first fixer 3 on the left side, the first torsion springs 5 are respectively connected between the left side and the right side of the second fixer 4 on the right side and the first fixer 3 on the right side, the number of the first torsion springs 5 is four, the first torsion springs 5 are wound on the second fixer 4, the upper die cover 2 is connected between the two second fixers 4, go up the contact of mould lid 2 and forming die frame 1, go up the mould lid 2 top left and right sides and all open and have the mouth of moulding plastics 21, be equipped with reinforcing mechanism 6 on the forming die frame 1, be equipped with cooling forming mechanism 7 on the forming die frame 1.

Referring to fig. 2 to 5, the reinforcing mechanism 6 includes a rotating disc 61, a second torsion spring 62, a joint rod 63, a reinforcing device 64 and a limit rod 65, the rotating disc 61 is rotatably connected to the middle of the rear portion of the forming mold frame 1, the second torsion spring 62 is connected between the rotating disc 61 and the forming mold frame 1, the second torsion spring 62 is wound on the front side of the rotating disc 61, the joint rod 63 is rotatably connected to the left and right sides of the rotating disc 61, the limit rod 65 is welded to the middle of the left and right sides of the rotating disc 61, the reinforcing device 64 is slidably connected to the two limit rods 65, the reinforcing device 64 is in contact with the forming mold frame 1 after moving, the reinforcing device 64 on the left side is rotatably connected to the joint rod 63 on the left side, and the reinforcing device 64 on the right side is rotatably connected to the joint rod 63 on the right side.

Referring to fig. 1, 2, 6, 7 and 8, the cooling and forming mechanism 7 includes a liquid outlet pipe 71, a liquid storage tank 72, a limiting plate 73 and an extension spring 74, the liquid outlet pipe 71 is wound around the left and right sides of the forming mold frame 1, the front and rear sides of the liquid outlet pipe 71 pass through the forming mold frame 1, the upper portions of the two liquid outlet pipes 71 are communicated with the liquid storage tank 72, the rear sides of the bottoms of the two liquid storage tanks 72 are connected with the extension spring 74 through hooks, the rear sides of the two liquid outlet pipes 71 are connected with the limiting plate 73 in a sliding manner, the extension spring 74 on the left side is connected with the limiting plate 73 on the left side, the extension spring 74 on the right side is connected with the limiting plate 73 on the right side, and the two limiting plates 73 are provided with flow ports 75.

When people need to produce the zinc alloy plate, people can use the forming and stacking integrated zinc alloy plate production equipment, firstly, a refrigerant is injected into the liquid storage tank 72, the liquid outlet pipe 71 is blocked by the limiting plate 73, so that the refrigerant cannot flow backwards through the liquid outlet pipe 71, then, people manually rotate the rotating disc 61, so that the connecting rod 63 moves, the reinforcing device 64 moves inwards along the limiting rod 65 to be contacted with the forming die frame 1, the second torsion spring 62 is twisted and deformed, after the reinforcing device 64 reinforces the forming die frame 1, people inject the liquid zinc alloy into the forming die frame 1, the upper die cover 2 and the partition plate 22 through the injection port 21, after the zinc alloy is filled among the forming die frame 1, the upper die cover 2 and the partition plate 22, people stop injecting the liquid zinc alloy into the forming die frame 1, and the partition plate 22 divides the forming die frame 1 into three sides, three formed zinc alloy plates are stacked together, so that the forming and stacking effect is achieved, people manually move the limiting plate 73 upwards, the stretching spring 74 is compressed, the circulation port 75 moves upwards, when the circulation port 75 is overlapped with the liquid outlet pipe 71, refrigerant flows backwards through the liquid outlet pipe 71, the liquid outlet pipe 71 is wound on the forming die frame 1, the refrigerant cools the formed zinc alloy plates, so that the cooling effect is achieved, then the refrigerant flows out through the liquid outlet pipe 71, when cooling is completed, people loosen the limiting plate 73, so that the stretching spring 74 resets to drive the limiting plate 73 to move downwards and reset, the circulation port 75 moves downwards, then the limiting plate 73 blocks the liquid outlet pipe 71, meanwhile, people loosen the rotating disc 61, so that the second torsion spring 62 resets to drive the rotating disc 61 to rotate reversely and reset, and the connecting rod 63 rotates reversely, and then reinforcement 64 moves along gag lever post 65 outside and keeps away from forming die frame 1, then people manually rotate cope match-plate pattern 2 to make second fixer 4 rotate, make first torsion spring 5 twist deformation, people will pile together three zinc alloy plates afterwards and take out and cut it, take out the back, people loosen cope match-plate pattern 2, thereby make first torsion spring 5 reset and drive second fixer 4 counter-rotation, make cope match-plate pattern 2 counter-rotation reset and forming die frame 1 contact.

Example 2

On the basis of embodiment 1, referring to fig. 3, 9 and 10, the forming mold further includes a locking mechanism 8, the locking mechanism 8 includes a latch 81, a stopper 82, first fixing shafts 83 and first compression springs 84, the latch 81 is connected to the upper side of the front portion of the upper mold cover 2, two first fixing shafts 83 are welded to the front side of the forming mold frame 1, the stopper 82 is connected to the two first fixing shafts 83 in a sliding manner, the latch 81 contacts with the stopper 82 after moving, the first compression springs 84 are connected between the two stoppers 82 and the forming mold frame 1, and the first compression springs 84 are wound on the first fixing shafts 83.

Referring to fig. 3, 11, 12 and 13, the mold cover plate expansion preventing mechanism 9 is further included, the mold cover plate expansion preventing mechanism 9 includes a push rod 91, a sliding frame 92, a fixing plate 93, a second compression spring 94 and a lower push rod 95, the push rod 91 is connected to the front sides of the two stiffeners 64, the fixing plates 93 are welded to the left and right sides of the front portion of the forming mold frame 1, the sliding frame 92 is connected to the two fixing plates 93 in a sliding manner, the push rod 91 on the left side is connected to the sliding frame 92 on the left side in a sliding manner, the push rod 91 on the right side is connected to the sliding frame 92 on the right side in a sliding manner, the second compression spring 94 is connected between the sliding frame 92 on the left side and the fixing plate 93 on the left side, the second compression spring 94 is connected between the sliding frame 92 on the right side and the fixing plate 93 on the right side, the second compression spring 94 is wound around the rear side of the sliding frame 92, the lower push rod 95 is connected to the upper sides of the two sliding frames 92 in a sliding manner, the lower press rod 95 moves to contact the upper mold cover 2.

Referring to fig. 1, 3 and 14, the liquid circulation opening mechanism 10 is further included, the liquid circulation opening mechanism 10 includes a connecting frame 101, a first rotating frame 102, a second fixing shaft 103 and a third fixing shaft 105, the connecting frame 101 is connected to lower sides of the two sliding frames 92, the second fixing shaft 103 is welded to left and right sides of a front portion of the forming mold frame 1, the first rotating frame 102 is rotatably connected to the two second fixing shafts 103, the first rotating frame 102 on the left side is rotatably connected to the connecting frame 101 on the left side, the first rotating frame 102 on the right side is rotatably connected to the connecting frame 101 on the right side, the third fixing shaft 105 is connected to lower sides of front portions of the two limiting plates 73, sliding grooves 104 are formed in the two first rotating frames 102, the third fixing shaft 105 on the left side is slidably connected to the sliding groove 104 on the left side, and the third fixing shaft 105 on the right side is slidably connected to the sliding groove 104 on the right side.

Referring to fig. 1, 2, 3 and 15, the molding die further includes a limiting mechanism 11, the limiting mechanism 11 includes a second rotating frame 111, a bayonet pin 112 and a third compression spring 113, the second rotating frame 111 is welded on the rotating disc 61, the bayonet pin 112 is connected to the upper side of the second rotating frame 111 in a sliding manner, the third compression spring 113 is connected between the bayonet pin 112 and the second rotating frame 111, the third compression spring 113 is wound on the rear side of the bayonet pin 112, a bayonet slot 114 is formed in the rear portion of the molding die holder 1, and the bayonet pin 112 contacts the bayonet slot 114 after moving.

When people need to take out the cooled and formed zinc alloy plate, people can rotate the upper die cover 2 by force, so that the latch 81 rotates under the action of pulling force, when the latch 81 rotates to contact the stopper 82, the latch 81 drives the stopper 82 to move outward, so that the first compression spring 84 is compressed, when the latch 81 continues to rotate away from the stopper 82, the first compression spring 84 resets to drive the stopper 82 to move inward and reset, the upper mold cover 2 rotates reversely to drive the latch 81 to rotate reversely, when the latch 81 rotates in the reverse direction to contact the stopper 82, the latch 81 drives the stopper 82 to move outward, so that the first compression spring 84 is compressed, when the latch 81 continues to rotate away from the stopper 82, the first compression spring 84 resets to drive the stopper 82 to move inward to lock the latch 81, so that a locking effect is achieved, and the molding die holder 1 is prevented from being opened easily.

The reinforcing device 64 moves inwards to drive the pushing rod 91 to move inwards, so that the sliding frame 92 moves downwards, the second compression spring 94 is compressed, the lower compression rod 95 moves downwards to contact with the upper mold cover 2, the pressing effect is realized, the phenomenon that the upper mold cover 2 is opened under the action of thermal expansion when injection molding is carried out is avoided, the reinforcing device 64 moves outwards to drive the pushing rod 91 to move outwards, the second compression spring 94 resets to drive the sliding frame 92 to move upwards to reset, the lower compression rod 95 moves upwards, then, people can manually move the lower compression rod 95 forwards, when the lower compression rod 95 moves forwards to a proper position, people can manually rotate the upper mold cover 2, after the upper mold cover 2 covers the forming mold frame 1, people manually move the lower compression rod 95 backwards to a proper position.

The sliding frame 92 moves downwards to drive the connecting frame 101 to move downwards, so that the first rotating frame 102 rotates, the third fixing shaft 105 moves upwards, the limiting plate 73 moves downwards, the automatic cooling effect is achieved, manpower is saved, the sliding frame 92 moves upwards to drive the connecting frame 101 to move upwards, the first rotating frame 102 rotates reversely, the third fixing shaft 105 moves downwards, and the limiting plate 73 moves downwards.

The third compression spring 113 of initial condition is in the state by the tensile, the rolling disc 61 rotates and drives second rotating turret 111 and rotate, thereby make bayonet lock 112 rotate, when bayonet lock 112 rotates and draw-in groove 114 contact, third compression spring 113 resets and drives bayonet lock 112 forward movement to in the draw-in groove 114, effect of blocking has been realized with this, when people need antiport rolling disc 61, people can manually move bayonet lock 112 backward, when bayonet lock 112 backward movement kept away from draw-in groove 114, rolling disc 61 antiport drives second rotating turret 111 antiport, thereby make bayonet lock 112 antiport.

Various other modifications and changes may be made by those skilled in the art based on the above-described technical solutions and concepts, and all such modifications and changes should fall within the scope of the claims of the present invention.

Claims

1. A zinc alloy plate production device integrating molding and stacking is characterized by comprising a molding die frame (1), an upper die cover (2), partition plates (22), first fixers (3), second fixers (4) and first torsion springs (5), wherein the upper side of the rear part of the molding die frame (1) is connected with the two first fixers (3), the partition plates (22) are connected with the front side and the rear side in the molding die frame (1), the two first fixers (3) are respectively connected with the second fixers (4) in a rotating manner, the first torsion springs (5) are respectively connected between the left side and the right side of the second fixer (4) on the left side and the first fixer (3) on the left side, the first torsion springs (5) are respectively connected between the left side and the right side of the second fixer (4) on the right side and the first fixer (3) on the right side, and the first torsion springs (5) are wound on the second fixer (4), be connected with between two second fixer (4) and go up mold cover (2), it has injection molding mouth (21) all to open to go up mold cover (2) top left and right sides, a serial communication port, still including reinforcing mechanism (6) and cooling forming mechanism (7), be equipped with reinforcing mechanism (6) on forming die frame (1), consolidate forming die frame (1) through reinforcing mechanism (6) motion, avoid forming die frame (1) to warp because of the thermal expansion, be equipped with cooling forming mechanism (7) on forming die frame (1), cool off liquid zinc alloy through cooling forming mechanism (7).

2. The forming and stacking integrated zinc alloy plate production equipment according to claim 1, wherein the reinforcing mechanism (6) comprises a rotating disc (61), a second torsion spring (62), a connecting rod (63), a reinforcing device (64) and a limiting rod (65), the rotating disc (61) is rotatably connected to the middle of the rear part of the forming die frame (1), the second torsion spring (62) is connected between the rotating disc (61) and the forming die frame (1), the second torsion spring (62) is wound on the front side of the rotating disc (61), the connecting rod (63) is rotatably connected to the left side and the right side of the rotating disc (61), the limiting rod (65) is connected to the middle of the left side and the right side of the rotating disc (61), the reinforcing device (64) for reinforcing the forming die frame (1) is slidably connected to the two limiting rods (65), and the reinforcing device (64) on the left side is rotatably connected to the connecting rod (63), the right reinforcing device (64) is rotatably connected with the right connecting rod (63).

3. A forming-stacking integrated zinc alloy plate production apparatus as claimed in claim 2, wherein said cooling-forming mechanism (7) comprises a liquid outlet pipe (71) and a liquid storage tank (72), limiting plate (73) and extension spring (74), forming die frame (1) left and right sides has all been around drain pipe (71), forming die frame (1) is all passed to drain pipe (71) front and back both sides, two drain pipe (71) upper portions all communicate there is liquid reserve tank (72) that are used for the splendid attire refrigerant, two liquid reserve tank (72) bottom rear sides all are connected with extension spring (74), two drain pipe (71) rear sides all sliding type are connected with limiting plate (73), left extension spring (74) are connected with left limiting plate (73), extension spring (74) on right side are connected with limiting plate (73) on right side, all open circulation mouth (75) on two limiting plate (73).

4. The forming and stacking integrated zinc alloy plate production equipment as claimed in claim 3, further comprising a locking mechanism (8) for locking the upper mold cover (2), wherein the locking mechanism (8) comprises a latch (81), a stopper (82), first fixing shafts (83) and first compression springs (84), the latch (81) is connected to the upper side of the front portion of the upper mold cover (2), the two first fixing shafts (83) are connected to the inner front side of the forming mold frame (1), the stoppers (82) are connected to the two first fixing shafts (83) in a sliding manner, the first compression springs (84) are connected between the two stoppers (82) and the forming mold frame (1), and the first compression springs (84) are wound on the first fixing shafts (83).

5. The forming and stacking integrated zinc alloy plate production equipment as claimed in claim 4, further comprising a mold cover plate expansion prevention mechanism (9) for pressing down the upper mold cover (2), wherein the mold cover plate expansion prevention mechanism (9) comprises a push rod (91), a sliding frame (92), fixed plates (93), second compression springs (94) and a lower push rod (95), the push rod (91) is connected to the front sides of the two stiffeners (64), the fixed plates (93) are connected to the left and right sides of the front part of the forming mold frame (1), the sliding frame (92) is connected to the two fixed plates (93) in a sliding manner, the push rod (91) on the left side is connected to the sliding frame (92) on the left side in a sliding manner, the push rod (91) on the right side is connected to the sliding frame (92) on the right side in a sliding manner, the second compression springs (94) are connected between the sliding frame (92) on the left side and the fixed plates (93) on the left side, a second compression spring (94) is connected between the sliding frame (92) on the right side and the fixing plate (93) on the right side, the second compression spring (94) is wound on the rear side of the sliding frame (92), and lower pressing rods (95) are connected to the upper sides of the two sliding frames (92) in a sliding mode.

6. The forming and stacking integrated zinc alloy plate production equipment according to claim 5, further comprising a liquid circulation opening mechanism (10) for realizing automatic cooling, wherein the liquid circulation opening mechanism (10) comprises a connecting frame (101), a first rotating frame (102), a second fixed shaft (103) and a third fixed shaft (105), the connecting frame (101) is connected to the lower sides of the two sliding frames (92), the second fixed shaft (103) is connected to the left and the right of the front part of the forming die frame (1), the first rotating frame (102) is rotatably connected to the two second fixed shafts (103), the first rotating frame (102) on the left side is rotatably connected to the connecting frame (101) on the left side, the first rotating frame (102) on the right side is rotatably connected to the connecting frame (101) on the right side, the third fixed shaft (105) is connected to the lower sides of the front parts of the two limiting plates (73), the two first rotating frames (102) are respectively provided with a sliding chute (104), the left third fixed shaft (105) is connected with the left sliding chute (104) in a sliding manner, and the right third fixed shaft (105) is connected with the right sliding chute (104) in a sliding manner.

7. A forming and stacking integrated zinc alloy plate production device as claimed in claim 6, further comprising a limiting mechanism (11) for clamping the rotating disc (61), wherein the limiting mechanism (11) comprises a second rotating frame (111), a clamping pin (112) and a third compression spring (113), the second rotating frame (111) is connected to the rotating disc (61), the clamping pin (112) is connected to the upper side of the second rotating frame (111) in a sliding manner, the third compression spring (113) is connected between the clamping pin (112) and the second rotating frame (111), the third compression spring (113) is wound on the rear side of the clamping pin (112), and a clamping groove (114) is formed in the rear part of the forming die holder (1).

8. A forming-stacking-integrated zinc alloy plate production equipment according to claim 5, wherein the down-pressure rod (95) is made of damping material.