KR100583054B1 - Sleeve for Die casting machine - Google Patents

Abstract

The present invention relates to a sleeve of a die casting machine. The sleeve of the die casting machine according to the present invention includes a cylindrical body member having a hollow portion to allow the plunger to reciprocate, and a molten metal inlet penetrating between an outer circumferential surface and an inner circumferential surface of the body member so that molten metal can be injected into the hollow portion. In having,

Cooling water for cooling the body member heated by the molten metal injected through the molten metal inlet flows into one end of the body member, flows into the other end along the longitudinal direction of the body member, and then again one end of the body member. It is characterized in that it comprises a first cooling water circulation path to flow out to be discharged.

Die Casting, Plunger, Sleeve, Melt

Description

Sleeve for die casting machine

1 is a schematic diagram illustrating a sleeve of a conventional die casting.

2 is a schematic cross-sectional view of a sleeve of a die casting machine according to a preferred embodiment of the present invention.

3 is a schematic cross-sectional view taken along line III-III of FIG. 2.

4 is a schematic cross-sectional view taken along the line IV-IV of FIG. 2.

FIG. 5 is a schematic cross-sectional view taken along the line VV of FIG. 2.

<Description of the symbols for the main parts of the drawings>

100 ... sleeve 10 ... body member

11 ... body 12 ... hollow part

13 ... molten metal inlet 20 ... 1st cooling water circulation

21 ... Cooling water first inlet 22 .... Cooling water first inlet

23 ... hole 24 ... pipe

25 ... inlet 26 ... outlet

27 ... first space part 28 ... second space part

29 ... barrier 30 ... shield

31 ... 2nd inlet 33 ... through hole

The present invention relates to a sleeve of a die casting machine, and more particularly, by improving the cooling structure to prevent deformation of the shape by heat, thereby increasing durability, as well as products produced in die cast molds. In order to maintain this constant quality, the structure of the die casting machine is improved.

Die casting, one of the casting methods, refers to a process in which a molten metal (molten metal) is pressed into a mold having a predetermined shape at a pressure higher than atmospheric pressure, and pressed by casting until the end of solidification. This die-casting method is widely used because of the advantage of improving the accuracy of dimensions, maintaining the smoothness of the surface, reducing the cutting process and high-speed mass production. The sleeve and plunger of the diecasting machine for carrying out this diecasting method are shown in FIG. 1. The sleeve 1 has a hollow part 3 in a cylindrical shape. In addition, the hollow portion 3 of the sleeve 1 is connected to a mold (not shown) of a predetermined shape, and a molten metal inlet 2 is formed at one side of the sleeve 1. The molten metal m dissolved in a separate melting furnace is injected into the hollow part 3 in the sleeve 1 through the molten metal inlet 2. On the other hand, the plunger 4 is for pressurizing the molten metal m injected into the sleeve 1, and is reciprocated in the hollow part 3 of the sleeve 1, and is in direct contact with the molten metal m. Consisting of a plunger tip 4a and a plunger rod 4b coupled to the plunger tip 4a. When the molten metal m enters the hollow part 3 of the said sleeve 1, the plunger 4 moves and pressurizes this molten metal m. The molten metal m thus pressed is press-fitted into the mold via the hollow part 3. When a predetermined time elapses in the press-fitted state, the molten metal m is solidified in the mold to complete one cycle of the casting operation. Thereafter, the plunger 4 is moved back to its original position, and the molten metal m is injected into the molten metal inlet 2 to repeat the same casting operation cycle. Since the sleeve 1 is heated to a high temperature by the molten metal m during the repeated casting operation, the sleeve 1 must be cooled. If the heated sleeve 1 is not cooled rapidly, the sleeve 1 is deformed due to thermal expansion or the like, so that a gap is generated between the plunger 4 and the inner circumferential surface of the sleeve 1 so that the molten metal is removed by the plunger 4. The pressing force is reduced, which is not only a problem, but also may cause trouble in the reciprocating motion of the plunger 4.

As shown in FIG. 1, the sleeve 1 of the conventional die casting machine has a cooling water passage 5 at the opposite side of the molten metal inlet 2, that is, the molten metal m is collected by the pressure of the plunger 4. ) Is formed. Since the portion in which the cooling water passage 5 is formed is a portion placed before the molten metal m is pressed into the mold, the residence time of the molten metal m is relatively longer than that of the other portions of the sleeve 1. Accordingly, since the portion in which the cooling water channel m is formed is applied with relatively more heat than other portions, temperature is increased by circulating the cooling water along the circumferential direction of the sleeve 1 through the cooling water channel 5. To prevent.

However, the temperature rise of the sleeve 1 due to the molten metal m does not occur only in the above-described portion, but also the portion of the molten metal m accumulated through the molten metal inlet 2, as well as the path of the molten metal m. Occurs in the entire area of the sleeve 1. In addition, since the heat is conducted to the relatively low temperature portion, the entire region of the sleeve 1 is heated. However, as described above, the sleeve 1 of the conventional die casting machine has a coolant passage 5 formed only in a portion thereof, and thus does not cool the entire sleeve 1, so that the sleeve 1 is easily deformed or There was a problem such as breakage and the pressing force of the molten metal (m) by the plunger 4 is reduced, there was a problem that a defect occurs in the product produced in the mold.

The present invention is to solve the above problems, by improving the cooling structure to prevent deformation of the shape by heat to increase the durability, as well as to improve the structure, so that the product produced in the die-cast die can maintain a constant quality It is an object to provide a sleeve of a die casting machine.

The sleeve of the die casting machine according to the present invention for achieving the above object, the cylindrical body member having a hollow portion so that the plunger can reciprocate, and between the outer peripheral surface and the inner peripheral surface of the body member so that the molten metal can be injected into the hollow portion In the molten metal injection hole provided through the cooling water, the cooling water for cooling the main body member heated by the molten metal injected through the molten metal inlet flows into one end of the main body member and the other end along the longitudinal direction of the main body member It is characterized in that it comprises a first cooling water circulation path to flow out into the one end of the main body member and then discharged again.

According to the present invention, the first coolant circulation path includes a coolant first inlet formed at one end of the main body member so that the coolant flows into the main body member, and the coolant circulating the main body member outside the main body member. A plurality of coolant first outlets formed at one end of the main body member and disposed along a circumferential direction of the main body member, the plurality of coolant first outlets being formed along the longitudinal direction of the main body member and communicating with the first coolant inlet And a pipe which is provided in each of the plurality of holes and communicates with the hole at the other end side of the body member and communicates with the coolant first outlet at one end side of the body member. The space formed between the inner circumferential surface of the pipe and the outer circumferential surface of the pipe flows in the longitudinal direction of the body member. It forms an inflow path, it is preferable that the inside of the pipe to form a discharge path in which the cooling water flows along the longitudinal direction of the body member.

According to the present invention, the first space formed in an annular shape along the circumferential direction of the body member so that the coolant flowing into the coolant first inlet can be distributed along the circumferential direction of the body member and flow into the respective inflow paths. By the unit, the cooling water first inlet is in communication with each inlet, the cooling water discharged through the respective discharge paths to the ring-shaped along the circumferential direction of the body member so that the discharged to the cooling water first outlet It is preferable that the cooling water first outlet and the respective discharge passages communicate with each other by the second space part formed as follows.

In addition, according to the present invention, it is preferable that three coolant first inlets are formed along the circumferential direction of the body member, and two coolant first outlets are formed along the circumferential direction of the body member.

According to the present invention, it is preferable that the cross-sectional area of the inflow path of the first cooling water circulation path is 6.6 times or more than the cross-sectional area of the discharge path.

Further, according to the present invention, it is preferable that nine holes are formed along the circumferential direction of the main body member.

Further, according to the present invention, a second inlet for cooling water for cooling the body member to the body member, a second outlet for outflow of the cooling water, and formed along the circumferential direction of the body member And a second cooling water circulation path including a through hole communicating with the second inlet port and the second outlet port, wherein the second cooling water circulation path is spaced apart from the first cooling water circulation path in the longitudinal direction of the body member, and the body member. It is preferable to be disposed on the other end side of the body member along the longitudinal direction of the two.

Hereinafter, with reference to the accompanying drawings, it will be described in more detail with respect to the sleeve of the die casting machine according to a preferred embodiment of the present invention.

FIG. 2 is a schematic cross-sectional view of a sleeve of a die casting machine according to a preferred embodiment of the present invention, FIG. 3 is a schematic cross-sectional view taken along line III-III of FIG. 2, and FIG. 4 is a schematic cross-sectional view taken along line IV-IV of FIG. 2. 5 is a schematic cross-sectional view taken along the line V-V of FIG.

2 to 5, the sleeve 100 of the die casting machine according to the preferred embodiment of the present invention includes a main body member 10 and a first coolant circulation path 20.

The body member 10 has a substantially cylindrical shape, the body 11 having a substantially annular cross section, and the hollow portion 12 formed along the longitudinal direction of the body 11 so that the plunger (not shown) can be reciprocated. Equipped with. In addition, a molten metal inlet 13 penetrating between an outer circumferential surface and an inner circumferential surface of the body 11 so that molten metal dissolved from an external melting furnace into the hollow portion 12 may be injected into one end of the main body member 10. ) Is formed. On the other hand, the other end of the hollow portion 12 is in communication with the mold of the predetermined shape so that the molten metal injected into the hollow portion 12 can be press-fit into the mold of the predetermined shape.

The first cooling water circulation path 20 is for cooling the main body member 10 heated by a high temperature molten metal injected through the molten metal inlet 13 to increase the temperature, and the first coolant first inlet 21 and the cooling water. The first outlet 22, the hole 23, and the pipe 24 are provided.

The cooling water first inlet 21 is for injecting cooling water into the body 11 of the body member 10, and has a predetermined depth along the radial direction of the body member 10 from an outer circumferential surface of the body 11. Cut out to form a groove. The cooling water first inlets 21 are formed at the lower end of one end of the main body member 10, and in this embodiment, three coolant first inlets 21 are disposed at regular angle intervals along the circumferential direction of the body 11 of the main body member 10. do.

The cooling water first outlet 22 is for discharging the cooling water circulated through the body 11 of the body member 10 to the outside of the body 11, and similarly to the cooling water first inlet 21, A groove is formed to a predetermined depth along the radial direction of the body member 10 from the outer circumferential surface of the body 11. The cooling water first inlet 22 is spaced apart from the cooling water first inlet 21, and is located opposite to the molten metal inlet 13 with the cooling water first inlet 21 therebetween. In this embodiment, two coolant first outlets 22 are disposed along the circumferential direction of the body 11 of the body member 10.

The hole 23 is formed to extend from one end surface of the body 11 to the other end surface side in the longitudinal direction of the body member 10. In the present embodiment, nine holes 23 are spaced apart at regular angles along the circumferential direction of the body member 10, but the molten metal inlet 13 is formed at an upper end of the body 11. This hole 23 is not disposed. Meanwhile, each of the plurality of holes 23 communicates with the cooling water first inlet 21 at one end thereof. In this embodiment, the diameter of this hole 23 is 16 mm and its cross-sectional area is approximately 200 mm ² .

The pipes 24 are installed in the nine holes 23, respectively, and are arranged long along the longitudinal direction of the holes 23. Moreover, this pipe 24 is hollow and both ends are open, and the long space through which the molten metal flows is formed in the inside. One end of the open ends of the pipe 24 communicates with the cooling water first outlet 22, and the other end communicates with the hole 23. In this embodiment, the outer diameter of the pipe 24 is 7mm, the inner diameter is 5.6mm, the inner cross-sectional area of the pipe is approximately 24mm ² and the outer cross-sectional area is approximately 38mm ² .

The space formed between the inner circumferential surface of the hole 23 and the outer circumferential surface of the pipe 24 may include the body (10) along the longitudinal direction of the body member (10) with the coolant flowing into the coolant first inlet (21). 11) to form an inlet (25) that can flow into. The cross-sectional area of the inflow passage 25 is 162 mm ² . On the other hand, the inside of the pipe 24 forms a discharge path 26 through which the coolant flowing along the inflow path 25 can be discharged along the longitudinal direction of the body member 10. The cross-sectional area of the discharge passage 26 is 24 mm ² as described above. Therefore, the cross-sectional area of the inflow passage 25 is approximately 6.6 times that of the cross-section of the discharge passage 26.

The plurality of inflow passages 25 and the cooling water first inlet 21 are communicated by the first space part 27. The first space portion 27 excavates between the plurality of holes 23 from one end of the body 11 to the other end to a predetermined depth to form an annular groove, and then the open surface of the groove portion. It is formed by sealing the with a blocking film (29). The blocking film 29 has an annular shape corresponding to the groove portion and nine through holes are formed to correspond to the pipe 24. The inner diameter of this through hole is equal to the outer diameter of the pipe 24. The blocking film 29 is joined to one end of the body 11 by welding or the like, with the pipes 24 extending slightly out of the hole 23 and fitted into the through holes of the blocking film 29, respectively. . The annular first space 27 formed by the annular groove and the blocking membrane 29 communicates with one ends of the inflow passage 25 and also communicates with the coolant first inlet 21. . Meanwhile, the pipes 24 are opened to the outside of the first space portion 27 while being fitted in the through holes of the blocking film 29.

The plurality of discharge paths 26 and the coolant first outlet 22 are communicated by the second space 28. The second space portion 28 is formed by the shielding member 30 and the blocking film 29 in which an annular groove is formed along the circumferential direction of the body 11. That is, the shielding member 30 is coupled to the shielding film 29 by welding or the like, so that the open surface of the annular groove of the shielding member 30 is sealed by the blocking film 29 so as to close the second space. A portion 28 is formed. Thus, the annular second space portion 28 formed by the shielding member 30 and the blocking film 29 is in communication with the coolant first outlet 22. The other ends of the plurality of pipes 24 are opened to the second space portion 28 so that the other end of the discharge passage 24 also communicates with the second space portion 28. The first space portion 27 and the second space portion 28 formed as described above are blocked by the barrier layer 29.

A second coolant circulation path 35 is formed at the other end of the body member 10. The second cooling water circulation path 35 is for cooling the portion where the molten metal collected by the pressure of the plunger (not shown) stays before being pressed into a predetermined mold (not shown). The second cooling water circulation path 35 includes a second inlet 31 for introducing cooling water into the body 11 of the body member 10, and the cooling water circulated through the body 11 with the body member 10. The second inlet 32 and the second inlet 31 and the second outlet 32 to interconnect the second outlet 32 so that the coolant can circulate the body 11 to the outside of the (11) and the body 11 It has a through hole 33 formed along the circumferential direction. In the present embodiment, the second cooling water circulation path 35 is disposed two spaced apart from each other on the other end side of the body 11 along the longitudinal direction of the body member (10). On the other hand, the second cooling water circulation path 35 is separated from each other and spaced apart from the first cooling water circulation path 20.

Hereinafter, a use example according to a preferred embodiment of the present invention will be described.

When molten metal is injected into the molten metal inlet 13 and accumulated at one end of the hollow part 12 of the main body member 10, a plunger (not shown) is provided at one end of the body 11 in the hollow part 12. The molten metal is moved from the side to the other end side to pressurize the molten metal to the other end of the hollow part 12. In this state, the plunger continuously presses the molten metal to press the molten metal into a predetermined mold (not shown). In this process, since the sleeve 100 is heated by the molten metal to increase the temperature, the entire region of the sleeve 100 is cooled by inflow and outflow of the cooling water through the first cooling channel and the second cooling channel.

That is, as shown by the arrow in Figure 3, when the coolant is introduced into the coolant first inlet 21, the coolant is the body of the body member 10 along the annular first space (27) ( 11) will be filled. When the coolant is filled in the first space portion 27 as shown by the arrow in FIG. 2, the coolant is distributed to each inflow path 25 so that the body along the plurality of inflow paths 25 is formed. 11) Flow inside. As the cooling water flows along the inflow path 25, the heat of the sleeve 100 is transferred to the cooling water, thereby lowering the temperature of the sleeve 100. Meanwhile, the cooling water flowing along the inflow path 25 flows into the discharge path 26 at the other end of the main body member 10 and flows along the discharge path 26. When the coolant continues to proceed and is discharged from the discharge path 26 to the second space portion 28, as shown by the arrows in FIG. 4, the coolant is guided along the second space portion 28 and the The cooling water is discharged to the first outlet. On the other hand, the coolant is introduced from the three coolant first inlets 21, but the coolant is discharged only through the two coolant first outlets 22. The first inlet 21 and the first outlet 22 are equal in diameter to each other 15mm. Therefore, since the total inflow cross-sectional area of the coolant is greater than the total discharge cross-section of the coolant, the inflow of the coolant is greater than the outflow amount in the state of continuously introducing the coolant. Is charged. If the coolant is continuously introduced, the first coolant circulation path 20 maintains a charged state, and thus the coolant is introduced and discharged so that the coolant is replaced in the first coolant circulation path 20. Compared to the case where the cross section of the first coolant circulation path is not completely filled but only partially filled, the cross section of the coolant in which the coolant is in direct contact with the heated body 11 is wide and the heated body 11 is also filled. Since the amount of cooling water is in direct contact with the large amount, the cooling efficiency of the sleeve 100 is increased. In addition, since the cross-sectional area of the inflow passage 25 is larger than that of the discharge passage 26 and the inflow passage 25 is in direct contact with the heated body 11, for example, the inflow passage 26 and the inflow passage Compared with the case where the furnace 25 is reversed and the cooling water is circulated in reverse, the cooling efficiency is excellent.

Meanwhile, while the coolant is circulated in the first coolant circulation path 20, the coolant is separately circulated in the second coolant circulation path 35. That is, the cooling water flowing into the second inlet 31 is circulated through the body 11 along the through hole 33 and cooled, and the process of flowing out through the second outlet 32 is continuously performed.

In this way, in the first cooling water circulation path 20, the cooling water is circulated along the longitudinal direction of the main body member 10 of the sleeve 100, thereby cooling the entire area of the sleeve 100 and thus the whole of the sleeve 100. Not only can the cooling be effectively performed in the region, but also the cooling water is circulated in the second cooling water circulation path 35 in the portion where the molten metal of the sleeve 100 is collected, thereby further increasing the cooling efficiency.

So far, nine holes 23 are described and illustrated as being arranged, but are not necessarily limited thereto, and may vary freely according to the size of the sleeve. In addition, three coolant first inlets 21 and two coolant first outlets 22 are described as being disposed, but are not necessarily limited thereto.

As described above, the sleeve of the die casting machine according to the present invention, by improving the cooling structure is prevented from deformation of the shape by heat to increase the durability, as well as the product produced in the die cast mold can maintain a constant quality There is an advantage.

Claims (7)

In the sleeve of the die-casting machine having a cylindrical body member having a hollow portion so that the plunger can reciprocate, and a molten metal inlet penetrating between the outer peripheral surface and the inner peripheral surface of the body member so that the molten metal can be injected into the hollow portion, Cooling water for cooling the body member heated by the molten metal injected through the molten metal inlet flows into one end of the body member, flows into the other end along the longitudinal direction of the body member, and then again one end of the body member. The first cooling water circulation path for flowing out to be discharged toward the inner and outer peripheral surface of the main body member is provided, The first cooling water circulation path, A first coolant inlet formed at one end of the main body member to allow the coolant to flow into the main body member; A first coolant outlet formed at one end of the main body member such that the coolant circulated through the main body member can be discharged to the outside of the main body member; A plurality of holes disposed along the circumferential direction of the main body member and formed to extend in the longitudinal direction of the main body member and communicating with the coolant first inlet port; It is installed in each of the plurality of holes, and comprises a pipe in communication with the hole on the other end side of the body member and in communication with the first outlet of the cooling water on one end side of the body member, A long space formed between the inner circumferential surface of the hole and the outer circumferential surface of the pipe forms an inflow path through which the cooling water flows along the longitudinal direction of the body member, and the inside of the pipe discharges the cooling water flowing along the longitudinal direction of the body member. Forming a furnace, The cooling water by the first space portion formed in an annular shape along the circumferential direction of the body member so that the cooling water flowing into the cooling water first inlet can be distributed along the circumferential direction of the body member and flow into the respective inflow paths. The first inlet and each inlet are in communication, The cooling water first outlets and the respective discharge paths are formed by a second space part formed in an annular shape along the circumferential direction of the main body member so that the cooling water discharged through the respective discharge paths may be collected and discharged to the cooling water first outlets. Sleeves of a die casting machine, characterized in that they are in communication. delete delete The method of claim 1, The cooling water first inlet is formed in three along the circumferential direction of the body member, the cooling water first outlet is formed in the two circumferential direction of the body member sleeve of the die casting machine. The method of claim 1, The sleeve of the die casting machine, characterized in that the cross-sectional area of the inflow path of the first cooling water circulation path is 6.6 times or more than the cross-sectional area of the discharge path. The method of claim 1, The sleeve of the die-casting machine, characterized in that nine holes are formed along the circumferential direction of the body member. The method of claim 1, A second inlet for introducing coolant for cooling the body member into the body member, a second outlet for outflowing the cooling water, and a circumferential direction of the body member, the second inlet and the second outlet And a second coolant circulation path including a through hole communicating with the The second cooling water circulation path is spaced apart from the first cooling water circulation path in the longitudinal direction of the main body member and is mutually isolated, and is disposed on the other end side of the main body member along the longitudinal direction of the main body member. Sleeve of die-casting machine.

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