CN114147200B - Fast-disengaging massive amorphous alloy product die casting device - Google Patents

Abstract

The invention discloses a quick-release type die casting device for a blocky amorphous alloy product, which relates to the technical field of amorphous alloy production and processing. After vacuum and low-temperature cooling treatment, the die-casting operation is completed, the push plate automatically pushes the formed amorphous alloy product out of the static die cavity, and the amorphous alloy door product falls onto the conveying frame for collection treatment, so that the rotary type rapid stripping and die-casting operation of the amorphous alloy product can be realized, the working efficiency is high, and the operation is convenient and rapid; can be effectively to the diversified cooling treatment of the multilayer of first supporting disk and second supporting disk, the inside coolant with quiet module contact of second supporting disk constantly switches over, can further strengthen the inside coolant heat exchange treatment efficiency of second supporting disk to further strengthen the cooling treatment effect to amorphous alloy goods.

Description

Fast-disengaging massive amorphous alloy product die casting device

Technical Field

The invention relates to the technical field of amorphous alloy production and processing, in particular to a quick-release type massive amorphous alloy product die casting device.

Background

The amorphous alloy is solidified by super-quenching, atoms are not arranged in order to be crystallized when the alloy is solidified, the obtained solid alloy is in a long-range disordered structure, molecules (or atoms and ions) forming the alloy are not in a spatially regular periodicity, and crystal grains and crystal boundaries of the crystalline alloy do not exist. The amorphous alloy has a plurality of unique properties, such as excellent magnetism, corrosion resistance, wear resistance, high strength, hardness and toughness, high resistivity, electromechanical coupling performance and the like. The die casting process is often used for near-net forming of parts with complex structures, and the preparation of amorphous alloys has extremely strict requirements on oxygen content, so that the vacuum melting die casting equipment is adopted on the premise of industrial application of amorphous alloys.

The existing die-casting device for the amorphous alloy products is mostly formed by one-to-one die-casting in the die-casting process, and the separation operation of the die-cast amorphous alloy products is not convenient enough.

Disclosure of Invention

The invention aims to provide a quick-release type die casting device for a massive amorphous alloy product, which aims to solve the problems in the background technology.

In order to solve the technical problems, the invention provides the following technical scheme: the utility model provides a cubic metallic glass goods die-casting device of formula of taking off soon, includes support frame, die-casting frame and carriage, the die-casting frame with the carriage respectively with the support frame rotates to be connected, the die-casting is erect in the carriage top, the support frame outer wall is equipped with the motor, motor output shaft with die-casting frame fixed connection, the motor pass through the belt with the carriage is connected.

Further, the die-casting frame includes first supporting disk and second supporting disk, first supporting disk with the second supporting disk rotates to be connected, first supporting disk outer wall is kept away from second supporting disk one side with support frame fixed connection, second supporting disk outer wall is kept away from first supporting disk one side is equipped with the back shaft, motor output shaft with back shaft fixed connection, second supporting disk outer wall is close to first supporting disk one side evenly is equipped with the quiet mould subassembly that a plurality of annular distributes, first supporting disk outer wall one side top center activity be equipped with quiet mould subassembly assorted movable mould subassembly, movable mould subassembly outer wall is kept away from second supporting disk one side is equipped with electric putter, first supporting disk outer wall in movable mould subassembly below be equipped with quiet mould subassembly assorted silo down.

Furthermore, the outer wall of the movable die assembly is close to one side of the second supporting disk and is provided with a movable die cavity, the outer wall of the static die assembly is close to one side of the first supporting disk and is provided with a static die cavity, the inner part of the static die cavity is provided with a movably connected push plate, the outer wall of the static die assembly is arranged on the outer side of the movable die assembly in an up-and-down symmetrical mode and is provided with a movably connected guide rod, one end of the static die assembly is provided with a movably connected ball, the outer wall of the first supporting disk is provided with a first annular slide rail matched with the first annular slide rail, the inner wall of the first supporting disk is provided with a first annular slide rail matched with the first annular slide rail, the outer wall of the first supporting disk is provided with a first rack horizontally on one side of the spring, the outer wall of the push plate is close to one side of the first rack and is provided with a second rack horizontally, the inner wall of the static die assembly is provided with a first gear and a second gear which are rotatably connected between the first rack and the second gear, and the second gear are meshed with the second rack respectively, and the second gear are meshed with the second rack.

Furthermore, the top of the first supporting disc is provided with an injection molding opening, the injection molding opening is connected with the movable membrane assembly through an injection molding pipe, a first movable cavity matched with the movable membrane assembly is arranged in the first supporting disc, and the first movable cavity provides a movement space and a movement space for the movable membrane assembly.

Furthermore, the inside second movable cavity that is equipped with of second supporting disk with first rack assorted second, the inside third movable cavity that is equipped with of second supporting disk with second rack assorted, the inside fourth movable cavity that is equipped with of second supporting disk with guide bar assorted, the inside installation cavity that is equipped with of second supporting disk with first gear with second gear assorted, for first gear, second gear, first rack and second rack provide installation and motion space.

Further, first supporting disk is inside to be equipped with first water storage chamber, second supporting disk outer wall one side extends first water storage intracavity portion is equipped with the connecting pipe, the connecting pipe with first water storage chamber rotates to be connected, the inside second water storage chamber that is equipped with of connecting pipe, first water storage chamber with second water storage chamber link up.

Further, first support dish inside in the first water storage chamber outside is equipped with third water storage chamber, third water storage chamber with first water storage chamber link up, third water storage chamber extends to the movable mould subassembly outside, first support dish inside in the third water storage chamber outside is equipped with first annular chamber, first support dish inside in the first annular chamber outside is equipped with a plurality of fourth water storage chamber, fourth water storage chamber passes through first annular chamber with the third water storage chamber link up, the annular chamber, second support dish inside in the second water storage chamber outside is equipped with fifth water storage chamber, fifth water storage chamber with the second water storage chamber link up, fifth water storage chamber extends to the inside and the outside of stationary mould subassembly, second support dish inside in the fifth water storage chamber outside is equipped with the second annular chamber, second support dish inside in the second annular chamber outside is equipped with a plurality of sixth water storage chamber, the sixth water storage chamber passes through the second with the fifth water storage chamber link up.

Furthermore, first water storage chamber outer wall is kept away from second water storage chamber one side is equipped with the inlet tube, inlet tube one end extends to the first supporting disk outside, first supporting disk outer wall top is equipped with the outlet pipe, the outlet pipe with fourth water storage chamber link up, the business turn over operation of coolant of being convenient for.

Furthermore, the first water storage cavity is rotatably connected with the connecting pipe through a plurality of support rings, annular grooves, sealing rings and sealing grooves.

Further, the conveying frame comprises a driving roller and a driven roller which are connected in a rotating mode, the driving roller and the driven roller are connected through a conveying belt, and the motor is connected with the driving roller through a belt and is used for conveying the amorphous alloy product.

Compared with the prior art, the invention has the following beneficial effects:

1. according to the invention, by arranging a die casting frame, a conveying frame, a first supporting disc, a second supporting disc, a push plate, a guide rod and a blanking groove, when a static die assembly moves to be aligned with a movable die assembly, a movable die cavity and the static die cavity are closed, materials are injected between the static die cavity and the movable die cavity, after vacuum and low-temperature cooling treatment, die casting operation is completed, the movable die assembly is separated from the static die assembly, a motor is started simultaneously, the static die assembly moves towards the blanking groove along a first annular slide rail, a ball on the guide rod slides into an arc-shaped groove, a spring rebounds and extends, the guide rod moves towards the outer side of the static die assembly under the pushing of the spring, a first rack moves outwards along with the guide rod horizontally, the first rack drives a first gear to rotate anticlockwise, the first gear drives a second gear to rotate clockwise, the second gear drives the second rack to move towards the outer side of the static die assembly, further drives the push plate to move outwards along the static die cavity, the push plate pushes out a formed amorphous alloy product from the static die cavity, the blanking frame falls into the amorphous alloy groove, and the amorphous alloy product falls onto the conveying frame for collection treatment; the motor continues to drive the second supporting disk to perform rotary motion, the pushing plate is completely contracted into the static mold cavity, the motor continues to rotate to wait for next injection molding and die-casting processing operation, the rotary type rapid stripping and die-casting operation on the amorphous alloy product can be realized, the working efficiency is high, and the operation is convenient and rapid.

2. The invention can effectively carry out multi-layer multi-azimuth cooling treatment on the first supporting disk and the second supporting disk by arranging the first water storage cavity, the connecting pipe, the second water storage cavity and the third water storage cavity, meanwhile, in the injection molding process, the movable mold component pushes the static mold component, so that the adverse effect of the cooling medium in the first supporting disk on the injection molding process is avoided, the cooling medium in the second supporting disk directly enters the static mold component, the amorphous alloy product can be effectively and rapidly cooled by the static module, and simultaneously when the amorphous alloy product rotates along with the second supporting disk, before the amorphous alloy product enters the blanking groove, the distance between the amorphous alloy product and the static die assembly is not changed, at the moment, the distance between the amorphous alloy product and the cooling medium in the second supporting disk is not changed, but along with the rotation of the second support plate, the cooling medium in the second support plate rotates along with the rotation, the cooling medium in the second support plate continuously generates turbulent motion in the rotation process of the second support plate, can effectively strengthen the self heat exchange movement between the cooling media in the second supporting disk, so that the temperature distribution of the cooling media in the second supporting disk is more uniform, can effectively strengthen the heat exchange between the cooling medium in the second supporting disk and the cooling medium in the first supporting disk, can further strengthen the heat exchange treatment efficiency of the cooling medium in the second supporting disk, thereby further enhancing the cooling treatment effect of the amorphous alloy product, in addition, in the rotating process of the static module component, the cooling medium in the second supporting disk and contacted with the static module component is continuously switched, the amorphous alloy product on the static die assembly can be further enhanced to be cooled and cooled, and the continuous quick-release die-casting cooling forming of the amorphous alloy product is ensured.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

FIG. 1 is a front elevational view of the invention as a whole;

FIG. 2 is a front sectional view of the present invention as a whole;

FIG. 3 is a side sectional view of the die-cast frame of the present invention;

FIG. 4 is an enlarged schematic view at A of FIG. 3 of the present invention;

FIG. 5 is an enlarged schematic view of the invention at B in FIG. 3;

FIG. 6 is a front view of a first support tray of the present invention;

FIG. 7 is a front view of the stationary die assembly of the present invention;

in the figure: 1. a support frame; 2. a die casting frame; 3. a belt; 4. a carriage; 5. a first support tray; 6. a second support disc; 7. a support shaft; 8. a motor; 9. a stationary die assembly; 10. a movable mold component; 11. an electric push rod; 12. a movable die cavity; 13. a static mold cavity; 14. pushing the plate; 15. a guide bar; 16. a ball bearing; 17. a first annular slide rail; 18. a second annular slide rail; 19. a discharging groove; 20. an arc-shaped groove; 21. a spring; 22. a first rack; 23. a second rack; 24. a first gear; 25. a second gear; 26. an injection molding port; 27. a first movable chamber; 28. a second movable chamber; 29. a third active cavity; 30. a fourth active cavity; 31. a mounting cavity; 32. a first water storage cavity; 33. a connecting pipe; 34. a second water storage cavity; 35. a third water storage cavity; 36. a first ring cavity; 37. a fourth water storage cavity; 38. a fifth water storage cavity; 39. a second ring cavity; 40. a sixth water storage cavity; 41. a water inlet pipe; 42. a drive roll; 43. a driven roller; 44. a conveyor belt; 45. and (4) a water outlet pipe.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The die-casting device for the fast-release bulk amorphous alloy product shown in fig. 1-7 comprises a support frame 1, a die-casting frame 2 and a conveying frame 4, wherein the die-casting frame 2 and the conveying frame 4 are respectively and rotatably connected with the support frame 1, the die-casting frame 2 is arranged above the conveying frame 4, a motor 8 is arranged on the outer wall of the support frame 1, an output shaft of the motor 8 is fixedly connected with the die-casting frame 2, the motor 8 is connected with the conveying frame 4 through a belt 3, the die-casting frame 2 comprises a first support disc 5 and a second support disc 6, the first support disc 5 is rotatably connected with the second support disc 6, the outer wall of the first support disc 5 is far away from one side of the second support disc 6 and fixedly connected with the support frame 1, a support shaft 7 is arranged on one side of the outer wall of the second support disc 6, the output shaft of the motor 8 is fixedly connected with the support shaft 7, a plurality of annularly distributed die assemblies 9 are uniformly arranged on one side of the first support disc 5, a movable die cavity assembly 10 is arranged on one side of the outer wall of the first support disc 5, a movable die cavity assembly 10 is provided with a movable die assembly 10, a movable die assembly 10 is arranged on one side of the outer wall of the movable die cavity assembly 10, a movable die assembly 10 is arranged on one side of the movable die cavity assembly 10 close to the movable die cavity assembly 10, a movable die assembly 10 close to the movable die cavity assembly 10 is arranged on the movable die assembly 10 close to the movable die cavity assembly 10, a movable die assembly 10 close to the movable die cavity assembly 10, a movable die cavity assembly 10 is arranged on the movable die cavity assembly 10, a movable die cavity assembly 10 close to the movable die cavity assembly 10, a movable die assembly 10 is arranged on the movable die cavity assembly 10 close to the movable die cavity assembly 10, the utility model discloses a fixed die assembly, including guide bar 15, quiet module 9, first support disc 5, first annular slide rail 17, first silo 19, second annular slide rail 18, first silo 19, push pedal 14, second rack 23, first module 9, quiet module 9, first gear 24 and second gear 25, first gear 24 respectively with second gear 25 with first rack 22 meshes, second gear 25 with second rack 23 meshes each other, first support disc 5 outer wall be equipped with first annular slide rail 17 assorted second annular slide rail 18 in first annular slide rail 17 inboard, lower silo 19 inner wall in second annular slide rail 18 inner wall is equipped with arc recess 20, guide bar 15 outer wall is kept away from ball 16 one end is equipped with spring 21, guide bar 15 outer wall in spring 21 one side level is equipped with first rack 22, push pedal 14 outer wall is close to first rack 22 one side level is equipped with second rack 23, quiet module 9 inner wall in be equipped with first gear 24 and second gear 25 of rotation connection between first rack 22 and the second rack 23.

The top of the first support disc 5 is provided with an injection molding port 26, the injection molding port 26 is connected with the movable membrane assembly 10 through an injection molding pipe, a first movable cavity 27 matched with the movable membrane assembly 10 is arranged inside the first support disc 5, amorphous alloy raw materials are injected from the injection molding port 26, and the first movable cavity 27 provides a movement space for the movable membrane assembly 10.

Second supporting disk 5 inside be equipped with first rack 22 assorted second activity chamber 28, second supporting disk 5 inside be equipped with second rack 23 assorted third activity chamber 29, second supporting disk 5 inside be equipped with guide bar 15 assorted fourth activity chamber 30, second supporting disk 5 inside be equipped with first gear 24 with second gear 25 assorted installation cavity 31, second activity chamber 28 provide installation and motion space for first rack 22, and third activity chamber 29 provides installation and motion space for second rack 23, and fourth activity chamber 30 provides installation and motion space for guide bar 15, and installation cavity 31 provides installation and motion space for first gear 24 and second gear 25.

The conveying frame 4 comprises a driving roller 42 and a driven roller 43 which are connected in a rotating mode, the driving roller 42 is connected with the driven roller 43 through a conveying belt 44, the motor 8 is connected with the driving roller 42 through a belt 3, the motor 8 drives the driving roller 42 to rotate through the belt 3, and the driving roller 42 is matched with the driven roller 43 and the conveying belt 44 to convey amorphous alloy products.

The implementation mode specifically comprises the following steps: when the die-casting device is used, the die-casting frame 2, the conveying frame 4, the first supporting disk 5, the second supporting disk 6, the push plate 14, the guide rod 15 and the blanking groove 19 are arranged, the motor 8 is started, the motor 8 drives the second supporting disk 6 to rotate through the supporting shaft 7, the first supporting disk 5 is fixed, the static die assembly 9 on the second supporting disk 6 moves annularly along the first annular sliding rail 17, the guide rod 15 moves annularly along the second annular sliding rail 18, the guide rod 15 is supported by the rolling ball 16 in a rolling manner, the smooth and stable movement of the guide rod 15 along the inner side of the second annular sliding rail 18 is ensured, and meanwhile, the guide rod 15 can move into the arc-shaped groove 20; when the static die assembly 9 moves to be aligned with the movable die assembly 10, the electric push rod 11 is adjusted to extend, the electric cylinder push rod 11 pushes the movable die assembly 10 forwards, the movable die assembly 10 is matched with the static die assembly 9, the movable die cavity 12 and the static die cavity 13 are closed, injection molding is carried out from the injection molding opening 26, materials are injected between the static die cavity 13 and the movable die cavity 12, after vacuum and low-temperature cooling treatment, die-casting operation is completed, the electric push rod 11 is adjusted to contract, the movable die assembly 10 is separated from the static die assembly 9, the motor 8 is started simultaneously, the motor 8 drives the second supporting plate 6 to carry out rotary motion, the static die assembly 9 carries out rotary motion with an amorphous alloy product formed by die-casting, the static die assembly 9 moves towards the feeding groove 19 along the first annular slide rail 17, the guide rod 15 moves towards the feeding groove 19 along the second annular slide rail 18, when the guide rod 15 moves to the inner side of the blanking groove 19, the ball 16 on the guide rod 15 slides into the arc-shaped groove 20, the spring 21 rebounds and extends, the guide rod 15 moves towards the outer side of the static die assembly 9 under the pushing of the spring 21, the first rack 22 moves horizontally outwards along with the guide rod 15, the first rack 22 drives the first gear 24 to rotate anticlockwise, the first gear 24 drives the second gear 25 to rotate clockwise, the second gear 25 drives the second rack 23 to move towards the outer side of the static die assembly 9, and further drives the push plate 14 to move outwards along the static die cavity 13, the push plate 14 pushes out the formed amorphous alloy product from the static die cavity 13, the amorphous alloy product enters the blanking groove 19 to fall downwards, and the amorphous alloy door product falls onto the conveying frame 4 to be collected; the motor 8 continues to drive the second supporting disk 6 to perform rotary motion, the guide rod 15 moves out of the arc-shaped groove 20 and enters the second annular slide rail 18, the second annular slide rail 18 pushes the guide rod 15 back, the guide rod 15 moves towards the inner side of the static die assembly 9, the spring 21 is compressed, the first rack 22 moves towards the inner side of the static die assembly 9 along with the guide rod 15, the first rack 22 drives the first gear 24 to perform clockwise rotary motion, the first gear 24 drives the second gear 25 to perform anticlockwise rotary motion, the second gear 25 rotates to drive the second rack 23 to perform horizontal motion towards the inner side of the static die assembly 9, further, the second rack 23 drives the push plate 14 to move inwards along the static die cavity 13, the push plate 14 is completely retracted into the static die cavity 13, the next injection molding and die casting processing operation is waited for continuous rotation, rotary type rapid stripping and die casting operation of amorphous alloy products can be realized, the working efficiency is high, and the operation is convenient and rapid.

As shown in fig. 1-fig. 2, a first water storage cavity 32 is arranged inside the first supporting disk 5, a connecting pipe 33 is arranged inside the first water storage cavity 32 and extends from one side of the outer wall of the second supporting disk 6, the connecting pipe 33 is rotatably connected with the first water storage cavity 32, a second water storage cavity 34 is arranged inside the connecting pipe 33, and the first water storage cavity 32 is communicated with the second water storage cavity 34; inside in first water storage chamber 32 outside of first support disc 5 is equipped with third water storage chamber 35, third water storage chamber 35 with first water storage chamber 32 link up, third water storage chamber 35 extends to the movable mould subassembly 10 outside, inside in of first support disc 5 is equipped with first annular cavity 36 in the third water storage chamber 35 outside, inside in of first support disc 5 first annular cavity 36 outside is equipped with a plurality of fourth water storage chamber 37, fourth water storage chamber 37 passes through first annular cavity 36 with third water storage chamber 35 link up, inside in of second support disc 6 second water storage chamber 34 outside is equipped with fifth water storage chamber 38, fifth water storage chamber 38 with second water storage chamber 34 link up, fifth water storage chamber 38 extends to the inside and the outside of static mould subassembly 9, inside of second support disc 6 in the fifth water storage chamber 38 outside is equipped with second annular cavity 39, inside of second support disc 6 in the second water storage chamber 39 outside is equipped with a plurality of sixth water storage chambers 40, sixth water storage chamber 40 passes through with fifth annular cavity 38.

First water storage chamber 32 outer wall is kept away from second water storage chamber 34 one side is equipped with inlet tube 41, 41 one end of inlet tube extends to the 5 outsides of first supporting disk, 5 outer wall tops of first supporting disk are equipped with outlet pipe 45, outlet pipe 45 with fourth water storage chamber 37 link up, and inside cooling water or other coolant sent into first water storage chamber 32 from inlet tube 41, the coolant that gets into fourth water storage chamber 37 inside discharged from outlet pipe 45, the coolant's of being convenient for business turn over operation.

First water storage chamber 32 with rotate through a plurality of support ring, ring channel, sealing ring and seal groove between the connecting pipe 33 and be connected, the support ring cooperates with the ring channel and realizes the rotation between connecting pipe 33 and first water storage chamber 32 and connect, and sealing ring and seal groove cooperation carry out sealed processing between connecting pipe 33 and first water storage chamber 32.

The implementation mode specifically comprises the following steps: when the cooling device is used, by arranging the first water storage cavity 32, the connecting pipe 33, the second water storage cavity 34, the third water storage cavity 35, the first annular cavity 36, the fourth water storage cavity 37, the fifth water storage cavity 38, the second annular cavity 39 and the sixth water storage cavity 40, cooling media are sent into the first water storage cavity 32, the cooling media in the first water storage cavity 32 enter the third water storage cavity 35 and the second water storage cavity 34 of the connecting pipe 33, the cooling media in the third water storage cavity 35 enter the first annular cavity 36, the cooling media in the first annular cavity 36 enter the fourth water storage cavity 37, and the first support disc 5 can be effectively subjected to multi-layer multi-azimuth cooling treatment; the cooling medium in the second water storage cavity 34 enters the fifth water storage cavity 38, the cooling medium in the fifth water storage cavity 38 enters the second annular cavity 39, the cooling medium in the second annular cavity 39 enters the sixth water storage cavity 40, multi-layer multi-azimuth cooling treatment of the second support disc 6 can be realized, in the process of injection molding, the movable mold assembly 10 pushes the stationary mold assembly 9 to prevent the cooling medium in the first support disc 5 from causing adverse effects on the injection molding process, the cooling medium in the second support disc 6 directly enters the stationary mold assembly 9, rapid cooling treatment can be effectively performed on the amorphous alloy product through the stationary mold assembly 9, meanwhile, in the process of rotational movement of the amorphous alloy product along with the second support disc 6, before the amorphous alloy product does not enter the blanking groove 19, the distance between the amorphous alloy product and the stationary mold assembly 9 is constant, at the moment, the distance between the amorphous alloy product and the cooling medium in the second support disc 6 is constant, but along with the rotational movement of the second support disc 6, the cooling medium in the second support disc 6 continuously cools the second support disc 6, the cooling medium in the second support disc 6 continuously, the process of cooling treatment, the cooling medium in the second support disc 6, the process, the cooling medium and the cooling treatment can be further uniformly cooled and the heat exchange treatment can be performed on the second support disc 6, the heat exchange efficiency of the second support disc 6, and the cooling medium in the heat exchange process of the second support disc 6 can be further, and the heat exchange medium, and the heat exchange efficiency of the heat exchange of the support disc 6 can be enhanced, the amorphous alloy product on the static die assembly 9 can be further enhanced to be cooled and cooled, and the continuous cooling and cooling forming of the fast-demoulding and die-casting processing of the amorphous alloy product is ensured.

The working principle of the invention is as follows:

referring to the attached drawings 1-7 of the specification, by arranging a die-casting frame 2, a conveying frame 4, a first supporting disc 5, a second supporting disc 6, a push plate 14, a guide rod 15 and a blanking groove 19, after vacuum and low-temperature cooling treatment, the die-casting operation is completed, a ball 16 on the guide rod 15 slides into an arc-shaped groove 20, the push plate 14 automatically pushes out a formed amorphous alloy product from a static die cavity 13, the amorphous alloy product enters the blanking groove 19 to fall downwards, and an amorphous alloy door product falls onto the conveying frame 4 for collection treatment; the motor 8 continues to drive the second supporting disk 6 to rotate, the push plate 14 is completely retracted into the static die cavity 13, and the second supporting disk continues to rotate to wait for the next injection molding and die casting processing operation, so that the rotary rapid stripping and die casting operation of the amorphous alloy product can be realized, the working efficiency is high, and the operation is convenient and rapid;

referring to the attached drawings 1-2 of the specification, through setting up first water storage chamber 32, connecting pipe 33, second water storage chamber 34, third water storage chamber 35, can be effectively to the diversified cooling treatment of the multilayer of first supporting disk 5 and second supporting disk 6, can further strengthen the inside coolant heat exchange treatment efficiency of second supporting disk 6, thereby further strengthen the cooling treatment effect to amorphous alloy goods, the coolant of the inside of second supporting disk 6 and quiet mould subassembly 9 contact constantly switches over, can further strengthen the amorphous alloy goods on quiet mould subassembly 9 and carry out cooling treatment, guarantee the continuous type of amorphous alloy goods and take off the cooling shaping of die-casting processing soon.

It should be noted that, in this document, relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described above, or equivalents may be substituted for elements thereof. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. The utility model provides a fast cubic metallic glass goods die-casting device of formula of taking off, includes support frame (1), die-casting frame (2) and carriage (4), its characterized in that: the die-casting frame (2) and the conveying frame (4) are respectively in rotary connection with the supporting frame (1), the die-casting frame (2) is arranged above the conveying frame (4), a motor (8) is arranged on the outer wall of the supporting frame (1), an output shaft of the motor (8) is fixedly connected with the die-casting frame (2), and the motor (8) is connected with the conveying frame (4) through a belt (3); the die casting frame (2) comprises a first supporting disc (5) and a second supporting disc (6), the first supporting disc (5) is rotatably connected with the second supporting disc (6), one side, away from the second supporting disc (6), of the outer wall of the first supporting disc (5) is fixedly connected with the supporting frame (1), one side, away from the first supporting disc (5), of the outer wall of the second supporting disc (6) is provided with a supporting shaft (7), an output shaft of a motor (8) is fixedly connected with the supporting shaft (7), one side, close to the first supporting disc (5), of the outer wall of the second supporting disc (6) is uniformly provided with a plurality of static die assemblies (9) distributed in an annular mode, a movable die assembly (10) matched with the static die assembly (9) is movably arranged at the center of the top of one side of the outer wall of the first supporting disc (5), one side, away from the outer wall of the movable die assembly (10) is provided with an electric push rod (11), and a blanking groove (19), matched with the movable die assembly (9), is arranged below the outer wall of the first supporting disc (5); the outer wall of the movable mold component (10) is close to one side of the second support disk (6) and is provided with a movable mold cavity (12), the outer wall of the static mold component (9) is close to one side of the first support disk (5) and is provided with a static mold cavity (13), a movable connection push plate (14) is arranged inside the static mold cavity (13), a guide rod (15) of a movable connection is arranged on the outer wall of the static mold component (9) in an up-and-down symmetry mode on the outer side of the movable mold component (10), a movable connection ball (16) is arranged at one end of the static mold component (9), a first annular slide rail (17) matched with the static mold component (9) is arranged on the outer wall of the first support disk (5), a second annular slide rail (18) matched with the guide rod (15) is arranged on the inner side of the first annular slide rail (17), a material discharging groove (19) is arranged on the inner wall of the first annular slide rail (17), an arc-shaped groove (20) is arranged on the inner wall of the first annular slide rail (18), a guide rod (21) is arranged on one side of the outer wall of the first annular slide rail (15), and a horizontal spring (22) is arranged on one side of the outer wall of the guide rod (16), the outer wall of the push plate (14) is close to one side of the first rack (22) and horizontally provided with a second rack (23), the inner wall of the static die assembly (9) is provided with a first gear (24) and a second gear (25) which are connected in a rotating mode between the first rack (22) and the second rack (23), the first gear (24) is meshed with the second gear (25) and the first rack (22) respectively, and the second gear (25) is meshed with the second rack (23).

2. The die casting device for the fast-release bulk amorphous alloy product according to claim 1, wherein: first support dish (5) top is equipped with mouthful (26) of moulding plastics, mould plastics mouthful (26) with movable mould subassembly (10) are through moulding plastics union coupling, first support dish (5) inside be equipped with first movable chamber (27) of movable mould subassembly (10) assorted.

3. The die casting device for the fast-release bulk amorphous alloy product according to claim 1, wherein: the inside of second supporting disk (6) be equipped with first rack (22) assorted second activity chamber (28), inside be equipped with of second supporting disk (6) with second rack (23) assorted third activity chamber (29), inside be equipped with of second supporting disk (6) with guide bar (15) assorted fourth activity chamber (30), inside be equipped with of second supporting disk (6) with first gear (24) with second gear (25) assorted installation cavity (31).

4. The die casting device for the fast-release bulk amorphous alloy product according to claim 1, wherein: first supporting disk (5) inside is equipped with first water storage chamber (32), second supporting disk (6) outer wall one side extends to first water storage chamber (32) inside is equipped with connecting pipe (33), connecting pipe (33) with first water storage chamber (32) rotate and connect, connecting pipe (33) inside is equipped with second water storage chamber (34), first water storage chamber (32) with second water storage chamber (34) link up.

5. The die casting device for the fast-release bulk amorphous alloy product according to claim 4, wherein: a third water storage cavity (35) is arranged inside the first supporting disc (5) and outside the first water storage cavity (32), the third water storage cavity (35) is communicated with the first water storage cavity (32), the third water storage cavity (35) extends to the outer side of the movable mould assembly (10), a first annular cavity (36) is arranged inside the first supporting disc (5) and outside the third water storage cavity (35), a plurality of fourth water storage cavities (37) are arranged inside the first supporting disc (5) and outside the first annular cavity (36), the fourth water storage cavity (37) is communicated with the third water storage cavity (35) through the first annular cavity (36), a fifth water storage cavity (38) is arranged in the second supporting disk (6) and outside the second water storage cavity (34), the fifth water storage cavity (38) is communicated with the second water storage cavity (34), the fifth water storage cavity (38) extends to the inside and the outside of the static module component (9), a second annular cavity (39) is arranged inside the second supporting disk (6) and outside the fifth water storage cavity (38), a plurality of sixth water storage cavities (40) are arranged in the second supporting plate (6) and outside the second annular cavity (39), the sixth water storage cavity (40) is communicated with the fifth water storage cavity (38) through the second annular cavity (39).

6. The die casting device for the fast-release bulk amorphous alloy product according to claim 5, wherein: first water storage chamber (32) outer wall is kept away from second water storage chamber (34) one side is equipped with inlet tube (41), inlet tube (41) one end extends to first supporting disk (5) outside, first supporting disk (5) outer wall top is equipped with outlet pipe (45), outlet pipe (45) with fourth water storage chamber (37) link up.

7. The die casting device for the fast-release bulk amorphous alloy product according to claim 5, wherein: the first water storage cavity (32) is rotatably connected with the connecting pipe (33) through a plurality of supporting rings, annular grooves, sealing rings and sealing grooves.

8. The die casting device for the fast-release bulk amorphous alloy product according to claim 1, wherein: carriage (4) are including drive roll (42) and driven voller (43) of rotating the connection, drive roll (42) with connect through conveyer belt (44) between driven voller (43), motor (8) pass through belt (3) with drive roll (42) are connected.

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