CN220805456U

CN220805456U - Circulation type cooling waterway structure of die

Info

Publication number: CN220805456U
Application number: CN202322648486.7U
Authority: CN
Inventors: 全典晖
Original assignee: Suzhou Zirong Precision Machinery Equipment Co ltd
Current assignee: Suzhou Zirong Precision Machinery Equipment Co ltd
Priority date: 2023-09-28
Filing date: 2023-09-28
Publication date: 2024-04-19
Anticipated expiration: 2033-09-28

Abstract

The utility model provides a circulating cooling waterway structure of a die, which comprises an upper casting die and a lower casting die, wherein an upper die cavity is formed in the bottom of the upper casting die, a lower die cavity is formed in the top of the lower casting die, a first cavity and a second cavity are symmetrically formed in the upper casting die on two sides of the upper die cavity, a first heat conduction passage is formed in the upper casting die between the first cavity and the second cavity, two ends of the first heat conduction passage are respectively communicated with the first cavity and the second cavity, and a third cavity and a fourth cavity are symmetrically formed in the lower casting die on two sides of the lower die cavity; according to the utility model, through the first heat conduction passage and the second heat conduction passage which are respectively arranged around the upper die cavity and the lower die cavity, the metal solution can be conducted to the temperatures on the upper casting die and the lower casting die to be quickly conducted into cold water, and the heat in the upper casting die and the lower casting die is quickly sent away through the cold water, so that the cooling speed of a casting piece is improved, and the production efficiency of the casting piece is improved.

Description

Circulation type cooling waterway structure of die

Technical Field

The utility model belongs to the technical field of casting processing, and particularly relates to a circulating cooling waterway structure of a die.

Background

Some metal parts with complex structures such as a textile machinery adjusting bracket are usually processed in a casting forming mode.

At present, the casting is easy to flow after the metal is liquefied, so that the casting can be taken out of the die after the metal is required to be reduced to a certain temperature and can keep the form of the metal, and the casting is naturally cooled after being kept still in the process of waiting for molding at present, however, the heat dissipation speed in the mode is slower, so that the waiting time is longer, and the production efficiency is difficult to improve.

In summary, the present utility model provides a circulating cooling water path structure for a mold to solve the above-mentioned problems.

Disclosure of utility model

In order to solve the technical problems, the utility model provides a circulating cooling water path structure of a die, which aims to solve the problems that in the prior art, the cooling speed of castings is full and the processing efficiency is affected.

The utility model provides a circulating cooling waterway structure of mould, includes mould and casting lower mould on the casting, the mould cavity has been seted up to the bottom of mould on the casting, the lower die cavity has been seted up at the top of casting lower mould, the inside of mould is gone up in the casting first cavity and second cavity have been seted up to the bilateral symmetry of going up the die cavity, the inside of mould is gone up in the casting be provided with first heat conduction passageway between first cavity with the second cavity, just the both ends of first heat conduction passageway respectively with first cavity with the second cavity is linked together, the casting lower mould is inside third cavity and fourth cavity have been seted up to the bilateral symmetry of lower die cavity, the inside second heat conduction passageway that has been seted up of casting lower mould between third cavity and the fourth cavity, just the both ends of second heat conduction passageway respectively with third cavity with fourth cavity is linked together.

Further, the number of the first heat conduction passages and the number of the second heat conduction passages are multiple, and the first heat conduction passages and the second heat conduction passages are uniformly distributed around the upper die cavity and the lower die cavity respectively.

Further, the cross-sectional shapes of the first heat conduction path and the second heat conduction path are circular.

Further, a pouring gate is arranged at the top of the upper casting die.

Further, the bottom of the upper casting die is symmetrically provided with a first connecting pipe and a first connecting hole at two sides of the upper casting die cavity, the first connecting pipe and the first connecting hole are respectively communicated with the second cavity and the first cavity, the top of the lower casting die is symmetrically provided with a second connecting pipe and a second connecting hole at two sides of the lower casting die cavity, and the second connecting pipe and the second connecting hole are respectively communicated with the third cavity and the fourth cavity.

Further, the number of the first connecting pipes, the first connecting holes, the second connecting pipes and the second connecting holes is two, the positions of the two first connecting pipes and the two second connecting holes are corresponding, and the positions of the two second connecting pipes and the two second connecting holes are corresponding.

Further, the top of the lower casting die is provided with a water baffle plate around the lower die cavity, the bottom of the upper casting die is provided with a water blocking groove around the upper die cavity, and the water baffle plate corresponds to the water blocking groove in position and is adaptive to the shape and the size.

Further, a water inlet joint and a water outlet joint are arranged on one side of the lower casting die, and the water inlet joint and the water outlet joint are respectively communicated with the third chamber and the fourth chamber.

Compared with the prior art, the utility model has the following beneficial effects:

According to the utility model, through the first heat conduction passage and the second heat conduction passage which are respectively arranged around the upper die cavity and the lower die cavity, the metal solution can be conducted to the temperatures on the upper casting die and the lower casting die to be quickly conducted into cold water, and the heat in the upper casting die and the lower casting die is quickly sent away through the cold water, so that the cooling speed of a casting piece is improved, and the production efficiency of the casting piece is improved.

Drawings

FIG. 1 is a perspective view of the novel present invention;

FIG. 2 is a schematic perspective view of an upper casting die of the present utility model;

FIG. 3 is a schematic perspective view of a casting lower die of the present utility model;

FIG. 4 is a schematic plan sectional view of the present utility model;

FIG. 5 is an enlarged partial schematic view of the utility model at A in FIG. 4

Fig. 6 is a schematic perspective cross-sectional view of the present utility model.

In the figure:

1. Casting an upper die; 2. casting a lower die; 3. an upper die cavity; 4. a lower die cavity; 5. a first chamber; 6. a second chamber; 7. a first heat conduction path; 8. a third chamber; 9. a fourth chamber; 10. a second heat conduction path; 11. a sprue gate; 12. a first connection pipe; 13. a first connection hole; 14. a second connection pipe; 15. a second connection hole; 16. a water baffle; 17. a water blocking groove; 18. a water inlet joint; 19. and a water outlet joint.

Detailed Description

Embodiments of the present utility model are described in further detail below with reference to the accompanying drawings and examples. The following examples are illustrative of the utility model but are not intended to limit the scope of the utility model.

As shown in fig. 1-6, the utility model provides a circulating cooling waterway structure of a mold, which comprises an upper casting mold 1 and a lower casting mold 2, wherein an upper mold cavity 3 is formed at the bottom of the upper casting mold 1, a lower mold cavity 4 is formed at the top of the lower casting mold 2, a first cavity 5 and a second cavity 6 are symmetrically formed at the two sides of the upper mold cavity 3 in the upper casting mold 1, a first heat conduction passage 7 is formed between the first cavity 5 and the second cavity 6 in the upper casting mold 1, two ends of the first heat conduction passage 7 are respectively communicated with the first cavity 5 and the second cavity 6, a third cavity 8 and a fourth cavity 9 are symmetrically formed at the two sides of the lower casting mold 4 in the lower casting mold 2, a second heat conduction passage 10 is formed between the third cavity 8 and the fourth cavity 9 in the lower casting mold 2, and two ends of the second heat conduction passage 10 are respectively communicated with the third cavity 8 and the fourth cavity 9.

The number of the first heat conduction passages 7 and the second heat conduction passages 10 is multiple, the first heat conduction passages 7 and the second heat conduction passages 10 are uniformly distributed around the upper die cavity 3 and the lower die cavity 4 respectively, so that heat in a casting is conveniently and uniformly taken away, and when liquid flows from the first heat conduction passages 7 and the second heat conduction passages 10, the heat in the die can be taken away, and the cooling speed of the die and the casting is increased.

The cross-sectional shapes of the first heat conduction path 7 and the second heat conduction path 10 are circular, and the circular cross section can accommodate more liquid to pass through, so that the heat dissipation effect is improved.

Wherein, a pouring gate 11 is arranged at the top of the upper casting mould 1, and the pouring gate 11 is used for pouring molten metal into the upper box mould cavity 3 and the lower box mould cavity 4.

Wherein, the bottom of the casting upper die 1 is symmetrically provided with a first connecting pipe 12 and a first connecting hole 13 at two sides of the upper die cavity 3, the first connecting pipe 12 and the first connecting hole 13 are respectively communicated with the second chamber 6 and the first chamber 5, the top of the casting lower die 2 is symmetrically provided with a second connecting pipe 14 and a second connecting hole 15 at two sides of the lower die cavity 4, and the second connecting pipe 14 and the second connecting hole 15 are respectively communicated with the third chamber 8 and the fourth chamber 9.

The number of the first connecting pipes 12, the first connecting holes 13, the second connecting pipes 14 and the second connecting holes 15 is two, the positions of the two first connecting pipes 12 and the two second connecting holes 15 are corresponding, the positions of the two second connecting pipes 14 and the two second connecting holes 15 are corresponding, and the first connecting pipes 12 and the second connecting pipes 14 can be respectively inserted into the first connecting holes 13 and the second connecting holes 15, so that the first chamber 5 and the third chamber 8, the second chamber 6 and the fourth chamber 9 are communicated, and corresponding sealing measures are arranged on the inner walls of the first connecting pipes 12, the second connecting pipes 14 and the first connecting holes 15, so that liquid leakage is prevented.

The top of the lower casting die 2 is provided with a water baffle 16 around the lower die cavity 4, the bottom of the upper casting die 1 is provided with a water baffle groove 17 around the upper die cavity 3, the water baffle 16 corresponds to the water baffle groove 17 in position, the shape and the size are matched, the water baffle 16 can be inserted into the water baffle groove 17, and water can be prevented from entering the upper die cavity 3 and the lower die cavity 4.

One side of the lower casting die 2 is provided with a water inlet joint 18 and a water outlet joint 19, the water inlet joint 18 and the water outlet joint 19 are respectively communicated with the third chamber 8 and the fourth chamber 9, the lower casting die 2 is communicated with a cold water circulation pipeline through the water inlet joint 18 and the water outlet joint 19, and cold water circulates in the upper casting die 1 and the lower casting die 2, so that heat in the upper casting die 1 and the lower casting die 2 is taken away.

The specific working principle is as follows:

before the utility model is used, the water inlet joint 18 and the water outlet joint 19 of the utility model are firstly connected with a cold water circulation pipeline, after the upper casting die 1 and the lower casting die 2 are assembled, pouring is carried out from the pouring opening 11, casting is carried out in the upper die cavity 3 and the lower die cavity 4, and gradually cooling and shaping are carried out.

The embodiments of the present utility model have been shown and described for the purpose of illustration and description, it being understood that the above embodiments are illustrative and not to be construed as limiting the utility model, and that variations, modifications, alternatives and variations may be made therein by one of ordinary skill in the art without departing from the scope of the utility model.

Claims

1. The utility model provides a circulating cooling water route structure of mould which characterized in that: including casting mould (1) and casting lower mould (2), mould cavity (3) have been seted up to the bottom of casting mould (1), lower die cavity (4) have been seted up at the top of casting lower mould (2), the inside of casting mould (1) is in first cavity (5) and second cavity (6) have been seted up to the bilateral symmetry of last die cavity (3), mould (1) inside is in first cavity (5) with be provided with first heat conduction passageway (7) between second cavity (6), just the both ends of first heat conduction passageway (7) respectively with first cavity (5) with second cavity (6) are linked together, third cavity (8) and fourth cavity (9) have been seted up to the bilateral symmetry of casting lower mould (2) inside be in between third cavity (8) and fourth cavity (9), just second heat conduction passageway (10) respectively with both ends of third cavity (8) and fourth cavity (9) are linked together.

2. The mold circulating cooling waterway structure of claim 1, wherein: the number of the first heat conduction passages (7) and the number of the second heat conduction passages (10) are multiple, and the first heat conduction passages (7) and the second heat conduction passages (10) are uniformly distributed around the upper die cavity (3) and the lower die cavity (4) respectively.

3. The mold circulating cooling waterway structure of claim 1, wherein: the cross-sectional shapes of the first heat conduction passage (7) and the second heat conduction passage (10) are circular patterns.

4. The mold circulating cooling waterway structure of claim 1, wherein: a pouring gate (11) is arranged at the top of the casting upper die (1).

5. The mold circulating cooling waterway structure of claim 1, wherein: the bottom of the casting upper die (1) is symmetrically provided with a first connecting pipe (12) and a first connecting hole (13) on two sides of the upper die cavity (3), the first connecting pipe (12) and the first connecting hole (13) are respectively communicated with the second cavity (6) and the first cavity (5), the top of the casting lower die (2) is symmetrically provided with a second connecting pipe (14) and a second connecting hole (15) on two sides of the lower die cavity (4), and the second connecting pipe (14) and the second connecting hole (15) are respectively communicated with the third cavity (8) and the fourth cavity (9).

6. The mold circulating cooling waterway structure of claim 5, wherein: the number of the first connecting pipes (12), the first connecting holes (13), the second connecting pipes (14) and the second connecting holes (15) is two, the positions of the two first connecting pipes (12) and the two second connecting holes (15) are corresponding, and the positions of the two second connecting pipes (14) and the two second connecting holes (15) are corresponding.

7. The mold circulating cooling waterway structure of claim 1, wherein: the top of the lower casting die (2) is provided with a water baffle (16) around the lower die cavity (4), the bottom of the upper casting die (1) is provided with a water baffle groove (17) around the upper die cavity (3), and the water baffle (16) corresponds to the water baffle groove (17) in position and is adaptive in shape and size.

8. The mold circulating cooling waterway structure of claim 1, wherein: one side of the lower casting die (2) is provided with a water inlet joint (18) and a water outlet joint (19), and the water inlet joint (18) and the water outlet joint (19) are respectively communicated with the third chamber (8) and the fourth chamber (9).