KR102280830B1 - Double pipe injection core chiller - Google Patents

Abstract

The present invention uses an inner core and an outer core to inject a double tube composed of an inner tube and an outer tube surrounding the inner tube, and an intermediate core is installed between the inner and outer cores and a spiral groove is formed to facilitate the circulation of cooling water. , It relates to a double tube injection core cooling device in which the injection time of the double tube is shortened because the inner tube and the outer tube are rapidly cooled due to the circulating coolant.
To this end, the present invention is provided with an outer core that is sandwiched between an upper mold and a lower mold to form a cavity for injecting an outer tube in a slider body reciprocating with a cylinder, and is fitted into the outer core and has a cavity for inner tube injection In the double tube injection core cooling apparatus having an inner core forming a, an intermediate core is provided between the outer core and the inner core, wherein the intermediate core has an outer circumferential surface in close contact with the inner circumferential surface of the outer core, and the inner core a cavity for injection of the inner tube is formed away from the outer peripheral surface of the; Supply spiral grooves are formed at a predetermined pitch on the outer peripheral surface of the intermediate core, and recovery spiral grooves are formed at a predetermined pitch between the pitches of the supply spiral grooves; The ends of the supply spiral groove and the recovery spiral groove are connected to each other so that the cooling water is circulated from the supply spiral groove to the recovery spiral groove to cool the outer tube.

Description

Double pipe injection core chiller

The present invention relates to a double tube injection core cooling device, and more particularly, an inner core and an outer core are used to inject a double tube composed of an inner tube and an outer tube surrounding the inner tube, and an intermediate core is formed between the inner and outer cores. It relates to a double tube injection core cooling device that shortens the injection time of the double tube by installing it and forming a spiral groove to facilitate the circulation of coolant.

In general, for core cooling of an injection mold, a water cooling type is used in which flow paths are formed on both sides of the upper mold as the center of the core and the cooling water is forcibly circulated in this flow path. Since the water cooling type gradually cools the core by circulating the cooling water, it is difficult to increase the cooling rate to the maximum, and it is difficult to quickly take out the molded product, thereby reducing productivity.

In consideration of this, the related art Patent No. 886756 discloses a first cooling water pipe inserted and installed inside the slide core pin to provide a cooling water inlet pipe, and a cooling water pipe installed to surround the first cooling water pipe and along the outer surface of the first cooling water pipe. A second cooling water pipe providing a discharge pipe, and a head portion installed on one side of the slide core pin, each having an inlet communicating with the first cooling water pipe and an outlet communicating with the second cooling water pipe, is provided. Since the tube and the second cooling water tube are made of a flexible material, a core cooling device that can be easily applied to a slide core having a curved structure has been proposed.

However, while the prior patent is suitable for injection of a single tube, it has a disadvantage that it cannot be applied to injection of a double tube having an inner tube and an outer tube surrounding it. That is, when the prior patent technology is applied, the inner tube can be cooled quickly, but there is a limitation in shortening the injection time because a separate cooling means is not provided for the outer tube surrounding it.

In addition, it is possible to cool the outer tube by forming a flow path in the upper mold or the lower mold surrounding the outer tube, but there is a limitation in rapidly cooling only the outer tube because the upper mold or the lower mold is also cooled.

The present invention was developed in consideration of the problems of the prior art, and an object of the present invention is to use an inner core and an outer core to inject a double tube composed of an inner tube and an outer tube surrounding the inner tube, and a middle between the inner and outer cores is used. By installing a core and forming a spiral groove to facilitate cooling water circulation, the injection time of the double pipe is shortened because the inner and outer pipes are close to each other and cooled rapidly due to the circulating cooling water, and also the cooling water supply line between the inner and middle cores It is to provide a double tube injection core cooling device that is unified and the mold is simplified.

To this end, the present invention is provided with an outer core that is sandwiched between an upper mold and a lower mold to form a cavity for injecting an outer tube in a slider body reciprocating with a cylinder, and is fitted into the outer core and has a cavity for inner tube injection In the double tube injection core cooling device having an inner core forming a, an intermediate core is provided between the outer core and the inner core, wherein the intermediate core has an outer peripheral surface in close contact with the inner peripheral surface of the outer core, and the inner core a cavity for injection of the inner tube is formed away from the outer circumferential surface of the; Supply spiral grooves are formed at a predetermined pitch on the outer peripheral surface of the intermediate core, and recovery spiral grooves are formed at a predetermined pitch between the pitches of the supply spiral grooves; The ends of the supply spiral groove and the recovery spiral groove are connected to each other so that the cooling water is circulated from the supply spiral groove to the recovery spiral groove to cool the outer tube.

According to the present invention, an intermediate core is provided between the inner core and the outer core. The intermediate core is in close contact with the inner circumferential surface of the outer core, and a cavity for injecting the inner tube is provided between the intermediate core and the inner core. In addition, since the outer core is wrapped with an upper mold and a lower mold to form a cavity for injecting the outer tube, double tube injection is possible.

In addition, the supply spiral groove and the recovery spiral groove are formed on the outer peripheral surface of the intermediate core to circulate the coolant, so that the outer core is cooled to lower the temperature of the injected outer tube. In addition, the inner core has a cooling tube and a circulation passage formed therein, so that the cooling water circulates, so the temperature of the inner tube can be quickly lowered, and the cooling water is circulated close to the inner tube and the outer tube, so that the inner tube and the outer tube without heat loss Since it can be cooled quickly, there is an advantage in that the injection time is shortened.

In addition, since the inner core and the intermediate core are connected through one cooling water supply line provided in the slider body, the configuration of the slider body is simplified.

1 is an exploded perspective view of a cooling device according to an embodiment of the present invention;
2 is an assembled perspective view of a cooling device according to an embodiment of the present invention;
3 is a perspective view of an intermediate core according to an embodiment of the present invention;
4 is a plan cross-sectional view of a cooling device according to an embodiment of the present invention;
5 is a side cross-sectional view of a cooling device according to an embodiment of the present invention;

1 to 5, the cooling device according to the embodiment of the present invention is provided with a slider body 10 reciprocating by a cylinder, and the slider body 10 has an inner core 20, an intermediate core 40 and an outer side on the front surface of the slider body 10. The core 30 is provided to protrude concentrically. A cavity for injection of the inner tube 52 is formed between the outer circumferential surface of the inner core 20 and the inner circumferential surface of the intermediate core 40 , and the outer core 30 has an upper mold 50 and a lower mold 51 . A cavity for injection of the outer tube 53 is formed.

The inner core 20 has a hollow cooling passage 21 formed therein, and the slider body 10 is provided with a cooling tube 22 that is loosely fitted to the cooling passage 21, so that the cooling passage 21 is provided. Cooling water is provided to flow between the inner circumferential surface and the outer circumferential surface of the cooling pipe 22 . And a recovery port 13 connected to the inside of the cooling pipe 22 is vertically formed in the slider body 10, and the end of the cooling pipe 22 is separated from the end of the cooling path 21, so that the cooling pipe ( 22) The inside and the cooling passage 21 are connected to each other. Accordingly, the cooling water flowing between the cooling passage 21 and the cooling tube 22 goes to the recovery port 13 through the inside of the cooling tube 22 .

The intermediate core (40) is formed with a hollow intermediate passage (41) is fitted to the outer periphery of the inner core (20) to form a cavity for forming the inner tube (52). And on the outer peripheral surface of the intermediate core 40, the supply spiral grooves 42 are formed at a predetermined pitch, and between the supply spiral grooves 42, the recovery spiral grooves 43 are formed at a predetermined pitch so as to be spaced at equal intervals. .

In addition, these spiral grooves 42 and 43 have a supply port 45 and a recovery port 46 formed in a portion corresponding to the slider body 10 at one end, and the opposite end is connected by a connection groove 44, The cooling water is circulated to the recovery line 12 along the supply port 45 , the supply spiral groove 42 , the connection groove 44 , the recovery spiral groove 43 , and the recovery port 46 . The supply line 11 and the recovery line 12 are formed in the slider body 10 in the form of a tube, and the supply line 11 and the recovery line 12 are connected through an inlet 14 and an outlet 15 through an inlet 14 and an outlet 15 . It is connected to the supply port 45 of the supply spiral groove 42 and the recovery port 46 of the recovery spiral groove 43 .
Since the supply line 11 is also connected to the supply spiral groove 42 through the inlet 14 in a state in which it is directly connected to the cooling passage 21 of the inner core 20, it is connected to the inner side as one supply line 11. Cooling water may be supplied to the cooling passage 21 of the core 20 and the supply spiral groove 42 of the intermediate core 40 , respectively.

The outer core 30 has a hollow outer passage 31 so that the outer peripheral surface of the intermediate core 40 is in close contact with the inner peripheral surface of the outer passage 31 . Therefore, since the open portions of the supply spiral groove 42 and the recovery spiral groove 43 are covered with the outer core 30 , the coolant circulated through these spiral grooves 42 and 43 is in direct contact with the outer core 30 . and the outer core 30 is actively cooled.

The cooling device of the embodiment of the present invention configured as described above can quickly lower the temperature of the injected inner tube 52 due to the cooling water circulating through the cooling tube 22 and the cooling passage 21 of the inner core 20, and also Since the coolant is circulated through the spiral grooves 42 and 43 of the intermediate core 40, the temperature of the injected outer tube 53 can be quickly lowered.

The slider body 10 is reciprocated toward the upper mold 50 and the lower mold 51 through a cylinder. During injection, the slider body 10 is advanced so that the outer core 30 is moved to the upper and lower molds ( When entering the interior of the 50 and 51, a cavity for forming the outer tube 53 is made. When the resin is injected in this state, the resin is filled into the cavity between the inner core 20 and the intermediate core 40 to form the inner tube 52 , and also the outer core 30 and the upper and lower molds 50 . The cavity between the 51 is filled with resin, and the outer tube 53 is molded.

After injection, before separating the mold, the temperature of the cores 20, 30, and 40 should be lowered so that the resin is sufficiently cured. In the cooling device according to an embodiment of the present invention, since cooling water is supplied along the supply line 11 and the cooling passage 21 , the temperature of the inner core 20 decreases, and the end of the cooling passage 21 is the end of the cooling tube 22 . Since the cooling water is circulated to the recovery port 13 along the cooling pipe 22, the inner pipe 52 is rapidly hardened.

In addition, the inlet 14 communicating with the supply line 11 is connected to the supply port 45 of the intermediate core 40, and the recovery port 46 of the intermediate core 40 is connected to the recovery line ( 12) is associated with Therefore, in the process of circulating the coolant to the supply spiral groove 42 through the inlet 14 and the supply port 45, it directly touches the inner circumferential surface of the outer core 30 to cool the outer core 30, so The formed outer tube 53 is rapidly hardened. Also, the cooling water flows from the supply spiral groove 42 to the recovery spiral groove 43 along the connection groove 44 and then exits to the recovery line 12 through the outlet 15, so that the cooling water continues to circulate.

In addition, since the supply spiral grooves 42 and the recovery spiral grooves 43 formed in the intermediate core 40 are alternately formed and connected through the connecting grooves 44 at the ends, the cooling water is supplied through these spiral grooves 42 and 43 is reciprocated along That is, since the cooling water advances along the axial direction of the intermediate core 40 and then moves backward along the axial direction, the cooling area is sufficient, and each of the spiral grooves 42 and 43 is formed so that the spiral grooves 42 and 43 are alternately formed. Since the pitch interval is sufficiently reduced and the slope is gentle, there is an advantage in that the coolant is smoothly circulated without stagnation.
In addition, since cooling water can be supplied to the inner core 20 and the intermediate core 40 through one supply line 11 , the configuration of the slider body 10 is simplified.

10: slider body 11: supply line
12: recovery line 20: inner core
21: cooling passage 22: cooling pipe
30: outer core 31: outer passage
40: intermediate core 41: intermediate passage
42: supply spiral groove 43: return spiral groove
44: connection groove

Claims (3)

An inner core, an intermediate core and an outer core are provided concentrically on the front surface of the slider body reciprocating with the cylinder, and a cavity for injection of the inner tube is formed between the outer circumferential surface of the inner core and the inner circumferential surface of the intermediate core, The core is wrapped with an upper mold and a lower mold to form a cavity for external tube injection, and supply spiral grooves are formed at a predetermined pitch on the outer peripheral surface of the intermediate core, and recovery spiral grooves are formed between pitches of the supply spiral grooves at a predetermined pitch. In the double pipe injection core cooling device formed as a cooling water for cooling the outer pipe to circulate,
The inner core has a hollow cooling passage formed therein, and the slider body is provided with a cooling tube that is loosely fitted into the cooling passage, so that the cooling water flows between the inner peripheral surface of the cooling passage and the outer peripheral surface of the cooling tube;
the end of the cooling pipe is provided to be separated from the end of the cooling passage so that the cooling water flows into the cooling pipe and then is provided toward a recovery port formed in the slider body;
and a supply line for simultaneously supplying cooling water between the supply spiral groove and the inner peripheral surface of the cooling passage and the outer peripheral surface of the cooling pipe is provided in the slider body. delete delete

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