CN114643342A - Pouring device for high-pressure casting die - Google Patents

Abstract

The invention discloses a pouring device for a high-pressure casting die, which comprises a base and a liquid storage chamber arranged above the base, wherein a vertical frame plate is fixedly arranged at the bottom of the liquid storage chamber, a coil pipe is rotatably arranged at the bottom of the liquid storage chamber, a sliding pipe sleeve is sleeved outside the coil pipe, a top plate is fixedly arranged at the upper end of a shaft column, one end of the coil pipe, far away from the sliding pipe sleeve, penetrates into the liquid storage chamber, and racks are slidably arranged at the bottom of the liquid storage chamber, which is positioned at two sides of a toothed ring. According to the injection molding device, firstly, in the process that the output part injects injection molding liquid into the mold cavity, the bottom end face of the output part and the injection height of the injection molding liquid are always kept in a close state, so that the high-temperature injection molding liquid is prevented from splashing out of the mold in the injection molding process, the safe operation of surrounding workers is guaranteed, secondly, the pressure plate compresses the inner space of the liquid storage cavity downwards, the injection molding liquid is rapidly injected into the mold cavity, the injection molding liquid is rapidly injected, and the purpose of improving the mold casting efficiency is achieved.

Description

Pouring device for high-pressure casting die

Technical Field

The invention relates to the technical field of die casting equipment, in particular to a pouring device for a high-pressure casting die.

Background

The casting mold is used for obtaining the structural shape of the part, other easily-formed materials are used for forming the structural shape of the part in advance, then the part is placed into the mold, a cavity with the same structural size as the part is formed in the sand mold, then the fluid liquid is poured into the cavity, and the part with the same structural shape as the mold can be formed after the fluid liquid is cooled and solidified.

The casting is one of injection molding modes of injecting a fluid liquid into a cavity of a mold, and is also a mode of injecting a relatively mature metal liquid into the mold, however, the existing casting device still has disadvantages, in the casting process, casting equipment is often arranged at a position higher than the position between the molds, when the metal liquid is poured downwards and injected into the mold, the liquid flowing from a high position falls into the cavity of the mold, a phenomenon that the high-temperature injection liquid splashes around can be generated, in the practical operation, the situation that a plurality of times of workers are scalded by the high-temperature injection liquid often occurs, so that the existing casting device has certain potential safety hazards when the high-temperature metal liquid is injected, the safety operation of the workers is not facilitated, meanwhile, in the using process of the existing casting device, a casting mode of pouring the liquid obliquely pouring of liquid storage equipment filled with the metal liquid is mostly adopted, so that the speed of the injection liquid into the mold cavity is relatively slow, the injection liquid needs to wait for a long time to fill the mold cavity, so that the mold casting efficiency is low, and the rapid production of cast parts is not facilitated.

Disclosure of Invention

The invention aims to: in order to solve the problems, a pouring device for a high-pressure casting die is provided.

In order to achieve the purpose, the invention adopts the following technical scheme: a pouring device for a high-pressure casting die comprises a base and a liquid storage chamber arranged above the base, wherein a vertical frame plate is fixedly arranged at the bottom of the liquid storage chamber, the vertical frame plate and the base are fixed through a support column, the side end of the liquid storage chamber is communicated with an input pipe, a coil pipe is rotatably arranged at the bottom of the liquid storage chamber, a sliding pipe sleeve is sleeved outside the coil pipe, a part for outputting injection molding liquid is arranged at the bottom of the sliding pipe sleeve, a pressing plate is slidably arranged inside the liquid storage chamber, a square blocking frame for limiting the sliding range of the pressing plate is fixedly arranged at the inner end of the liquid storage chamber, a shaft column is fixedly arranged at the upper end of the pressing plate, a top plate is fixedly arranged at the upper end of the shaft column, one end, far away from the sliding pipe sleeve, of the coil pipe penetrates into the liquid storage chamber and is communicated with the liquid storage chamber, a gear ring is fixedly arranged at the outer end of the coil pipe in the liquid storage chamber, racks are slidably arranged at two sides of the gear ring at the bottom of the liquid storage chamber, the rack is meshed with the toothed ring, a shell sleeve is mounted at the side end of the liquid storage chamber, a component for controlling the rack and the top plate to synchronously move is arranged in the shell sleeve, an anti-seepage plate is fixedly arranged on the upper sides of the toothed ring and the rack inside the liquid storage chamber, a liquid storage cavity with the anti-seepage plate as the bottom is formed in the liquid storage chamber, and the input end of the coil penetrates through the anti-seepage plate and is communicated with the liquid storage cavity.

Preferably, the outer end of the coil pipe is fixedly provided with a convex block, and a sliding rail matched with the convex block to slide is arranged in the sliding connection pipe sleeve.

Preferably, side brackets are fixedly arranged at the side ends of the sliding pipe sleeve, and vertical grooves matched with the side brackets to slide are formed in the vertical frame plates.

Preferably, the part for outputting the injection molding liquid is a first injection nozzle fixedly arranged at the bottom of the sliding connection pipe sleeve, two second injection nozzles arranged in the first injection nozzle in a sliding manner, and an assembly for controlling the two second injection nozzles to horizontally move.

Preferably, the first injection nozzle is communicated with the sliding connection pipe sleeve, and a branch pipe is communicated between the first injection nozzle and the two second injection nozzles.

Preferably, the component for controlling the horizontal movement of the two second nozzles is a telescopic mechanism arranged on the first nozzle, the upper ends of the second nozzles are fixedly provided with a support, and the free ends of the telescopic mechanism are fixed with the support.

Preferably, the part for controlling the rack and the top plate to synchronously move is a sliding connection frame arranged in the outer shell in a sliding mode, a linkage frame fixedly arranged at the bottom of the top plate and an assembly for controlling the linkage frame to vertically move.

Preferably, a support rod is fixedly arranged between the rack and the sliding connection frame, and a sliding groove matched with the support rod to penetrate and slide is formed in the liquid storage chamber.

Preferably, the inner end of the linkage frame is fixedly provided with a sliding block, and the inside of the sliding connection frame is provided with a strip-shaped groove matched with the sliding block to slide.

Preferably, the component for controlling the vertical movement of the linkage frame is a transmission arm which is rotatably arranged on the inner end face of the outer shell, the free end of the transmission arm is rotatably connected with the linkage frame, and a driving motor for controlling the transmission arm to rotate is mounted at the outer end of the outer shell.

In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that:

1. this application is through being equipped with the coil on holding the liquid room, be equipped with smooth pipe box on the coil, be equipped with first nozzle and second nozzle on smooth pipe box, the in-process of liquid of moulding plastics is injected into to the die cavity at output part, the coil is rotatory to be driven smooth pipe box rebound, thereby make first nozzle and second nozzle slow upwards lift up at the in-process of moulding plastics, output part's bottom terminal surface and the state that highly remains to press close to each other all the time of the injection of liquid of moulding plastics, avoid the liquid of moulding plastics of high temperature to spill the mould of in-process of moulding plastics, thereby reach the purpose of eliminating potential safety hazard in the mould casting process, staff's safe operation around the guarantee.

2. This application is through being equipped with the clamp plate in holding the liquid room, be equipped with the interlock frame on the roof, be equipped with driving motor and drive arm on the shell cover, the control supplies the part of the liquid output of moulding plastics to stretch into the chamber bottom of mould, it rotates through driving motor control drive arm, make the interlock frame drive clamp plate downstream, the inner space in liquid chamber is held in the compression, hold the inside high pressure state that forms in liquid chamber this moment, thereby make the liquid of moulding plastics pour into the inside to the die cavity fast, realize the quick injection to the liquid of moulding plastics, reach the purpose that improves mould casting efficiency.

Drawings

FIG. 1 illustrates a perspective view provided in accordance with an embodiment of the present invention;

fig. 2 illustrates a cross-sectional side view of a reservoir chamber provided in accordance with an embodiment of the invention;

FIG. 3 illustrates a cross-sectional top view of a reservoir provided in accordance with an embodiment of the present invention;

FIG. 4 illustrates a cross-sectional view of a slip-on sleeve provided in accordance with an embodiment of the present invention;

FIG. 5 illustrates a bottom view provided in accordance with an embodiment of the present invention;

fig. 6 is an exploded view showing the internal structure of a liquid storage chamber provided according to an embodiment of the present invention.

Illustration of the drawings:

1. a base; 2. a vertical frame plate; 201. a vertical groove; 3. a reservoir chamber; 301. a chute; 4. coiling; 401. a bump; 5. sliding to connect the pipe sleeve; 501. a slide rail; 6. side connection frames; 7. a first nozzle; 8. a second nozzle; 9. a support; 10. a telescoping mechanism; 11. a branch pipe; 12. a toothed ring; 13. a rack; 14. a strut; 15. a sliding connection frame; 1501. a strip-shaped groove; 16. a linkage frame; 17. a slider; 18. a drive arm; 19. a drive motor; 20. an input tube; 21. an impermeable plate; 22. a square blocking frame; 23. pressing a plate; 24. an outer shell; 25. a top plate; 26. and (4) a shaft column.

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.

Referring to fig. 1-6, the present invention provides a technical solution: a pouring device for a high-pressure casting die comprises a base 1 and a liquid storage chamber 3 arranged above the base 1, wherein a vertical frame plate 2 is fixedly arranged at the bottom of the liquid storage chamber 3, the vertical frame plate 2 and the base 1 are fixed through a support, an input pipe 20 is communicated with the side end of the liquid storage chamber 3, a coil pipe 4 is rotatably arranged at the bottom of the liquid storage chamber 3, a sliding pipe sleeve 5 is sleeved outside the coil pipe 4, a part for outputting injection molding liquid is arranged at the bottom of the sliding pipe sleeve 5, a pressure plate 23 is slidably arranged inside the liquid storage chamber 3, a square blocking frame 22 for limiting the sliding range of the pressure plate 23 is fixedly arranged at the inner end of the liquid storage chamber 3, a shaft column 26 is fixedly arranged at the upper end of the pressure plate 23, a top plate 25 is fixedly arranged at the upper end of the shaft column 26, one end, far away from the sliding pipe sleeve 5, of the coil pipe 4 penetrates into the liquid storage chamber 3 and is communicated with the liquid storage chamber 3, a toothed ring 12 is fixedly arranged at the outer end of the coil pipe 4, racks 13 are slidably arranged at two sides of the liquid storage chamber 3, the rack 13 is meshed with the toothed ring 12, a shell 24 is arranged at the side end of the liquid storage chamber 3, a part for controlling the rack 13 and a top plate 25 to move synchronously is arranged in the shell 24, an anti-seepage plate 21 is fixedly arranged in the liquid storage chamber 3 and positioned at the upper sides of the toothed ring 12 and the rack 13, a liquid storage chamber taking the anti-seepage plate 21 as the bottom is formed in the liquid storage chamber 3, the input end of the coil pipe 4 penetrates through the anti-seepage plate 21 to be communicated with the liquid storage chamber, an existing electromagnetic valve for controlling liquid circulation is arranged in the sliding connection pipe sleeve 5, injection liquid is filled into the liquid storage chamber 3 through the input pipe 20, a part for outputting the injection liquid is controlled to extend into the bottom of the cavity of the mold, then the electromagnetic valve is opened, the liquid storage chamber 3 and the part for outputting the injection liquid are communicated, the control pressure plate 23 moves downwards to compress the inner space of the liquid storage chamber, so that the liquid storage chamber is in a high-pressure state, and the injection liquid is quickly injected into the mold cavity through the output part, the injection molding liquid is rapidly injected, so that the purpose of improving the casting efficiency of the mold is achieved; in the process of injecting injection molding liquid into the die cavity by the output part, the coil pipe 4 rotates and drives the sliding pipe sleeve 5 to move along the vertical direction, so that the output part is slowly lifted upwards in the injection molding process, the bottom end face of the output part and the injection height of the injection molding liquid are always kept in a close state, the injection molding liquid with high temperature is prevented from splashing out of the die in the injection molding process, the purpose of eliminating potential safety hazards in the die casting process is achieved, and safety operation of surrounding workers is guaranteed.

Specifically, as shown in fig. 1 to 4, a protrusion 401 is fixedly disposed at an outer end of the coil pipe 4, a sliding rail 501 which is matched with the protrusion 401 to slide is disposed in the sliding pipe sleeve 5, a side bracket 6 is fixedly disposed at a side end of the sliding pipe sleeve 5, a vertical groove 201 which is matched with the side bracket 6 to slide is disposed in the vertical frame plate 2, the rotation of the coil pipe 4 is controlled, the protrusion 401 fixed at the outer end of the coil pipe 4 slides along the sliding rail 501, the sliding pipe sleeve 5 drives the injection liquid output component to move in the vertical direction through the pressing transmission of the protrusion 401 to the sliding rail 501, and in the vertical moving process of the sliding pipe sleeve 5, the side bracket 6 fixed on the sliding pipe sleeve 5 slides along the vertical groove 201 to limit the rotation of the sliding pipe sleeve 5, so as to ensure the stable transmission of the sliding pipe sleeve 5 by the coil pipe 4.

Specifically, as shown in fig. 1 to 5, the components for outputting the injection liquid are a first nozzle 7 fixedly arranged at the bottom of the sliding connection pipe sleeve 5, two second nozzles 8 slidably arranged in the first nozzle 7, and a component for controlling the two second nozzles 8 to horizontally move, the first nozzle 7 is communicated with the sliding connection pipe sleeve 5, a branch pipe 11 is communicated between the first nozzle 7 and the two second nozzles 8, the injection liquid in the liquid storage cavity is input into the first nozzle 7 through the coil pipe 4 and the sliding connection pipe sleeve 5, the first nozzle 7 is input into the two second nozzles 8 through the branch pipe 11, and finally the injection liquid is input into the mold cavity through the first nozzle 7 and the second nozzles 8.

Specifically, as shown in fig. 1-4, the subassembly of controlling two second nozzles 8 horizontal migration is telescopic mechanism 10 installed on first nozzle 7, the upper end of second nozzle 8 has set firmly support 9, telescopic mechanism 10's free end is fixed mutually with support 9, when moulding plastics, the staff can select two second nozzle 8's distribution distance according to the inner structure in the mould, telescopic mechanism 10 adopts current pneumatics, electronic or hydraulic drive's mode, it drives second nozzle 8 and slides along first nozzle 7 to start telescopic mechanism 10, adjust two second nozzle 8's distribution interval, thereby adjust the output range of injection molding liquid output unit, be applicable to the mould that the bottom is unsmooth differs in the die cavity, make the quick even injection molding liquid fill die cavity.

Specifically, as shown in fig. 1, fig. 2, fig. 3 and fig. 6, the components for controlling the synchronous movement of the rack 13 and the top plate 25 are a sliding connection frame 15 slidably disposed inside the housing 24, a linkage frame 16 fixedly disposed at the bottom of the top plate 25, and an assembly for controlling the vertical movement of the linkage frame 16, a support rod 14 is fixedly disposed between the rack 13 and the sliding connection frame 15, a sliding chute 301 for allowing the support rod 14 to slide therethrough is disposed inside the liquid storage chamber 3, a sliding block 17 is fixedly disposed at the inner end of the linkage frame 16, a strip-shaped groove 1501 for allowing the sliding connection frame 15 to slide along the sliding block 17 is disposed inside the sliding connection frame 15, the linkage frame 16 is controlled to drive the top plate 25 to move in the vertical direction, the top plate 25 drives the pressing plate 23 to compress the inner space of the liquid storage chamber downward through the shaft column 26, the sliding block 17 fixed on the linkage frame 16 slides along the strip-shaped groove 1501 during the downward movement of the linkage frame 16, the sliding connection frame 15 drives the two racks 13 to synchronously move in opposite directions along the horizontal direction through the support rod 14, the rack 13 will drive the coil 4 fixed with the toothed ring 12 to rotate in the moving process, so as to adjust the vertical positions of the first injection nozzle 7 and the second injection nozzle 8.

Specifically, as shown in the figure, the component for controlling the linkage frame 16 to move vertically is a transmission arm 18 rotatably disposed on the inner end face of the outer casing 24, the free end of the transmission arm 18 is rotatably connected with the linkage frame 16, a driving motor 19 for controlling the transmission arm 18 to rotate is mounted at the outer end of the outer casing 24, the transmission arm 18 is formed by two equal-length rod members which are rotatably connected, and the driving motor 19 is started to control the transmission arm 18 to rotate, so that the linkage frame 16 rotatably connected with the transmission arm 18 is driven to move in the vertical direction.

The previous description of the embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. A pouring device for a high-pressure casting mold comprises a base (1) and a liquid storage chamber (3) arranged above the base (1), and is characterized in that a vertical frame plate (2) is fixedly arranged at the bottom of the liquid storage chamber (3), the vertical frame plate (2) is fixed with the base (1) through a support column, a side end of the liquid storage chamber (3) is communicated with an input pipe (20), a coil pipe (4) is rotatably arranged at the bottom of the liquid storage chamber (3), a sliding pipe sleeve (5) is sleeved on the outer side of the coil pipe (4), a part for outputting injection molding liquid is arranged at the bottom of the sliding pipe sleeve (5), a pressing plate (23) is slidably arranged inside the liquid storage chamber (3), a square blocking frame (22) for limiting the sliding range of the pressing plate (23) is fixedly arranged at the inner end of the liquid storage chamber (3), and a shaft column (26) is fixedly arranged at the upper end of the pressing plate (23), a top plate (25) is fixedly arranged at the upper end of the shaft column (26), one end of the coil pipe (4) far away from the sliding connection pipe sleeve (5) penetrates into the liquid storage chamber (3), and is communicated with the liquid storage chamber (3), the outer end of the coil (4) is fixedly provided with a toothed ring (12) in the liquid storage chamber (3), racks (13) are arranged at the bottom of the liquid storage chamber (3) on two sides of the gear ring (12) in a sliding manner, the rack (13) is meshed with the toothed ring (12), the side end of the liquid storage chamber (3) is provided with an outer shell (24), the outer casing (24) is internally provided with a component for controlling the synchronous movement of the rack (13) and the top plate (25), an anti-seepage plate (21) is fixedly arranged in the liquid storage chamber (3) and positioned at the upper side of the gear ring (12) and the rack (13), a liquid storage cavity with an impermeable plate (21) as the bottom is formed in the liquid storage chamber (3), the input end of the coil (4) penetrates through the anti-seepage plate (21) and is communicated with the liquid storage cavity.

2. A casting device for a high-pressure casting die according to claim 1, characterized in that a projection (401) is fixedly arranged at the outer end of the coil (4), and a slide rail (501) which is matched with the projection (401) to slide is arranged in the slide connection pipe sleeve (5).

3. A casting device for high pressure casting die according to claim 2, characterized in that the side end of the slip pipe sleeve (5) is fixedly provided with a side bracket (6), and the inner part of the vertical frame plate (2) is provided with a vertical groove (201) matched with the side bracket (6) to slide.

4. A casting apparatus for a high pressure casting mold according to claim 1, wherein the means for feeding out the injection liquid is a first nozzle (7) fixed to the bottom of the slip pipe sleeve (5), two second nozzles (8) slidably disposed in the first nozzle (7), and an assembly for controlling the horizontal movement of the two second nozzles (8).

5. A casting device for high pressure casting moulds according to claim 4, characterised in that the first nozzle (7) communicates with a slip-on sleeve (5), and that a branch (11) communicates between the first nozzle (7) and the two second nozzles (8).

6. A casting device for high pressure casting mould according to claim 5, characterized in that the component controlling the horizontal movement of the two second nozzles (8) is a telescopic mechanism (10) mounted on the first nozzle (7), the upper end of the second nozzle (8) is fixedly provided with a bracket (9), and the free end of the telescopic mechanism (10) is fixed with the bracket (9).

7. The casting device for the high-pressure casting die as claimed in claim 6, wherein the parts for controlling the synchronous movement of the rack (13) and the top plate (25) are a sliding connection frame (15) arranged inside the outer casing (24) in a sliding mode, a linkage frame (16) fixedly arranged at the bottom of the top plate (25) and an assembly for controlling the vertical movement of the linkage frame (16).

8. A casting device for high pressure casting mould according to claim 7, characterized in that a support rod (14) is fixed between the rack (13) and the sliding connection frame (15), and the liquid storage chamber (3) has a sliding groove (301) inside which the support rod (14) is matched to slide through.

9. The casting device for the high-pressure casting die as claimed in claim 8, wherein a sliding block (17) is fixedly arranged at the inner end of the linkage frame (16), and a strip-shaped groove (1501) matched with the sliding block (17) to slide is formed in the sliding connection frame (15).

10. The casting device for the high-pressure casting die is characterized in that the component for controlling the vertical movement of the linkage frame (16) is a transmission arm (18) rotatably arranged on an inner end surface of the outer casing (24), the free end of the transmission arm (18) is rotatably connected with the linkage frame (16), and the outer end of the outer casing (24) is provided with a driving motor (19) for controlling the rotation of the transmission arm (18).

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