KR101093499B1 - Injection device, the device of the freeform draw - Google Patents

Abstract

The present invention relates to an apparatus for taking out an injection-molded preform from an injection molding machine and to moving it to another place. The present invention relates to a preform ejection device for an injection molding machine comprising:

A cooling substrate portion (C) configured by mounting the same number of cooling pipe bodies (1) on the substrate (5) as the number of preform molding portions formed on the mold (M) for forming the preform (P); and

The suction pipe 11 and the fixed pipe 12 are inserted into the cooling pipe body 1, and the preform P injection-molded in the mold M into the cooling pipe body 1 is composed of a double pipe. A takeover pipe 10 having a clearance gap formed between the 11 and the fixed pipe 12 to form a cooling air supply path 14; and,

An installation substrate 15 formed through the mounting hole 16 to which one end of the fixing tube 12 is fixed, and to be hermetically coupled to the bush 17; and

The installation substrate 15 is mounted on the suction pipe passage 21 for transmitting suction power to the suction passage 13 of the suction pipe 11 constituting the take over pipe 10 and the cooling air supply passage 14 to the cooling air. Take over part (T) consisting of a base substrate 20 having a supply pipe 22 for supplying a;

An actuating part (G) comprising a rack (25) and a pinion (26) and a forward and reverse motor (27) connected to the pinion (26) to slide the take-up part (T) in the cooling substrate part (C); It is to provide a preform ejection device for an injection molding machine, characterized in that provided.

Blowing device, takeover pipe, base, board part, hollow part, cooling board part, suction pipe path, supply pipe, base board, take over part, working part

Description

Injection device for injection molding machine {Injection device, the device of the freeform draw}

The present invention relates to an apparatus for taking out an injection-molded preform from an injection molding machine and to moving it to another place. More particularly, the present invention relates to a cooling means for cooling a high-temperature preform while taking over and moving an injection-molded preform in an injection molding machine. It relates to a preform ejection device for an injection molding machine having a.

In general, the preform injection-molded in the mold mounted on the injection machine is discharged in a high temperature state, the preform injection-molded at a high temperature is generally cooled by natural cooling.

Cooling the preform through natural cooling is likely to cause torsion during cooling of the preform. In addition, when the product is transported at a high temperature, the surface may be scratched even with a small impact, resulting in frequent defects. It happened.

In order to solve this problem, a take-out apparatus having a cooling means for taking over a preform molded from an injection mold and cooling it for a predetermined time has been proposed and used.

As shown in FIG. 1, a conventional extraction device is

On one side or both sides of the take-out plate body 202 is repeatedly installed in the longitudinal pipe body 200 vertically and continuously, the take-up pipe body 200 is formed in the outer periphery of the spiral cooling water circulation hole 201, the cooling water at the bottom The inlet hole 203 and the cooling water discharge hole 204 are formed, and the outer periphery of the take over pipe 200 is formed by sealing the cooling water circulation hole 201 by combining the closed pipe body 205.

The conventional take-out device having the above-described configuration is to take out the preform P formed in the mold of the injection device to the hollow portion 206 of the take over pipe 200, and the preform P is taken over for the take over pipe 200. ) Is cooled by the cooling water supplied to the cooling water circulation hole 201 formed in the outer periphery.

The take-out device having the above-mentioned cooling device is to circulate the cooling water in the takeover pipe 200 which takes over the preform P to force cooling, and its structure is quite complicated, so that it is difficult to manufacture the separate cooling water. Cooling water supply device for circulating is to be provided essentially.

In addition, in order to cool the preform discharged with high temperature with a coolant, a considerable cooling time is required, and it is natural that the productivity of the injection apparatus is lowered due to the delay of the cooling time.

The present invention is to solve the problems of the conventional preform extraction device described above is to solve the following problems.

First, to provide a drawer having a simple structure.

Secondly, an object of the present invention is to provide a take-out apparatus with improved cooling rate.

The present invention for solving the above object, the cooling substrate portion configured by mounting the same number of cooling pipe bodies as the number of preform molding portion formed in the mold for forming the preform on the substrate; Wow,

A turnover pipe which is inserted into the cooling pipe body and introduces a preform injection-molded from a mold into the cooling pipe body; And a take-up part, to which the take-up pipe is mounted, comprising a base board having a suction path and a supply path for supplying suction power and cooling air to the take-up pipe body; Wow,

An operation unit configured to elevate and operate by a pair of gears and a motor at a side portion of the base unit; Wow,

A compression device connected to the supply pipe part; It is to provide a preform extraction device provided with.

The extraction device of the present invention having the above-described configuration has a simple structure, which can be produced at low cost, and the cooling speed is remarkably improved by the cooling means using the heat dissipation fins. By doing so, it is possible to improve the cooling rate and obtain a rapid discharge of high heat.

A cooling substrate part configured by mounting the same number of cooling pipe bodies as the number of preform molding parts formed on the mold for molding the preform to the substrate;

A turnover tube which is inserted into the cooling tube body and introduces a preform injection-molded from a mold into the cooling tube; And a take-up part, to which the take-up pipe is mounted, comprising a base board having a suction path and a supply path for supplying suction power and cooling air to the take-up pipe body; Wow,

An operation unit configured to elevate and operate by a pair of gears and a motor at a side portion of the base unit; Wow,

A compression device connected to the take over part; It will be equipped with.

The present invention having such a configuration will be described in more detail with reference to the accompanying drawings.

2 is a cross-sectional view of a take-out apparatus applied to the present invention, Figures 3a, b, c is a cross-sectional view, a side view and a major part enlarged cross-sectional view of the takeover pipe to be applied to the present invention, Figure 4 is a cross-sectional view of the main part of the present invention. 5 a, b, c, d is an operating state diagram showing the operating state of the present invention.

A cooling substrate portion C formed by mounting the same number of cooling pipe bodies 1 on the substrate 5 as the number of preform molding portions formed on the mold M for forming the preform P; and

The suction pipe 11 and the fixed pipe 12 are inserted into the cooling pipe body 1, and the preform P injection-molded in the mold M into the cooling pipe body 1 is composed of a double pipe. A takeover pipe 10 having a clearance gap formed between the 11 and the fixed pipe 12 to form a cooling air supply path 14; and,

An installation substrate 15 formed through the mounting hole 16 to which one end of the fixing pipe 12 constituting the take over pipe 10 is fixed and sealed to the bush 17; and

To the base substrate 20 having a suction pipe passage 21 for transmitting suction force to the suction passage 13 of the suction pipe 11 and a supply pipe 22 for supplying cooling air to the cooling air supply passage 14. Take over part T is configured; And,

An injection machine consisting of a rack (25) and a pinion (26) for operating the take-up part (T) in the cooling substrate part (C) and a reverse rotation motor (27) for driving them; It is to provide a preform ejection device for the device.

The cooling pipe body 1 constituting the cooling substrate part C forms a plurality of heat dissipation fins 4 radially on the outer periphery of the main body 2 in which the hollow part 3 is formed, and the hollow part 3 ), And the tip end portion has the same shape as the outer shape of the incoming preform (P), but a clearance is formed between the incoming preform (P) and the inner wall (3 ') of the hollow portion (3) to the cooling air discharge path (7 The diameter is adjusted to form a).

The cooling air discharge passage 7 is formed such that the inner wall 3 'of the cooling pipe 1 is equal to the outer diameter of the preform P, and the plurality of discharge recesses 3a are formed in the outer wall 3'. The cooling air exhaust passage 7 can be formed by forming up to the end portion in the direction.

The fixed tube 12 fixed to the installation substrate 15 and the suction tube 11 fixed to the base substrate 20 are configured to have a clearance between each of the diameter difference to form a cooling air supply path 14. However, as a means for maintaining the cooling air supply passage 14 more efficiently, the interval maintaining protrusions 11 'and 12 are selectively provided at the outer circumferential edge of the suction pipe 11 or the inner circumferential edge of the fixed pipe 12 selectively. ') May be integrally formed to maintain the cooling air supply passage 14 at a uniform width.

In addition, as another means for maintaining the cooling air supply path 14, the space maintaining the integrally formed small support protrusions 31 protruding inwardly on both side ends of the suction pipe 11 and the fixed pipe 12 Combining the ring 30 can be configured to uniformly maintain the clearance of the cooling air supply path (14).

At the rear end of the cooling substrate portion C to which the main body 2 of the cooling pipe body 1 is fixed, a takeover pipe body 10 constituting the take-up part T is inserted to seal the fixed pipe 12 so as to slide. 8) and bush (9).

The suction pipe passage 21 and the supply passage 22 formed in the base substrate 20 constituting the take over part T are connected to the compressor 40 provided separately.

Reference numeral 100 is a cooling feeder.

The operation of the present invention extraction device configured as described above will be described.

As shown in FIG. 2, the preform P formed in the mold 101 of the injection molding machine is stopped in a state where the preform P is exposed to the outside by the mold 101 to be separated, and injection molding is performed. The cooling board part C equipped with the number of the takeover tubes 10 equal to the number of the preforms P is moved closer to the front of the preform P.

That is, when the cooling substrate portion C moves and stops near the lower portion of the preform P, the forward and reverse motor 27 mounted on one side of the rear portion of the cooling substrate portion C is driven to rotate the pinion 26. Then, the rack 25 engaged with the pinion 26 is moved to move the lifting portion T including the base substrate 20 up and down with a predetermined width.

The width at which the base substrate 20 moves up and down may include a length at which the tip of the take over tube 10 of the take over part T attached to the base substrate 20 corresponds to the tip of the cooling tube 1, or 2 to 5 mm. Protruding width is most suitable.

When the base substrate 20 moves, a push rod (not shown) built in the mold M is drawn to push the molded preform P into the takeover tube 10 to be in close contact with the tip portion.

When the preform P is brought into close contact with the take-up pipe 10 fixed to the installation board 15, the compressor 40 simultaneously operates to generate suction power, and the suction pipe 21 is formed through the suction pipe path 21 of the base substrate 20. 11) the outside air is sucked through the suction passage 13, and the preform P, which is close to the tip of the suction pipe 11, is sucked and fixed by the suction force.

Subsequently, when the base substrate 20 reverses again due to the reverse rotation of the forward and reverse rotation motor 27, the preform P is pulled to the hollow portion 3 of the cooling pipe 1 while the take over tube 10 moves backward. It is.

The lifting width of the take over pipe 10 moving forward and backward from the hollow portion 3 of the cooling pipe 1 is raised and lowered to the extent that 70 to 90% of the injection-molded preform P can be maintained. Adjusted to effect action.

When the injection-molded preform P is introduced into the hollow portion 3 of the cooling pipe 1 through the lifting operation of the base substrate 20 by the rack 25 and the pinion 26, the compressor 40 is compressed. A suction pipe for supplying compressed air to the supply line 22 of the base substrate 20 through a connecting pipe connected to an air outlet (not shown), and constituting the take over pipe 10 fixed to the supply pipe 22 ( Compressed air is supplied to the cooling air supply path 14 formed between the 11) and the fixed tube (12).

The compressed air is used as cooling air for cooling the preform (P), it can be supplied by cooling the temperature of the compressed air to a certain level by mounting a cooling device in the connection pipe to which the compressed air is supplied.

Since the compressed air is discharged to have a cooling function of discharging the heat of the preform P to the outside, it will be referred to as cooling air below.

As described above, the cooling air supplied from the compressor is supplied to the cooling air supply path 14 between the suction pipe 11 and the fixed pipe 12 through the supply pipe 22 of the base substrate 20.

The cooling air supplied through the cooling air supply path 14 is externally provided through the cooling air discharge path 7 formed between the inner wall 3 ′ of the hollow part 3 of the cooling pipe 1 and the preform P. The preform P is cooled by the forced air discharged, and the main body 2 of the cooling tube 1 heated by the heat of the drawn preform P is simultaneously cooled.

The heat dissipation fins 4 formed at the outer circumferential portion of the cooling pipe body 1 serve to more effectively cool the heated main body 2 by being introduced into the preform P.

In the present invention, the preform (P) coupled to the hollow portion 3 of the cooling pipe 1 and the hollow portion 3 is produced by adjusting the size so that a predetermined clearance gap occurs between the inner wall (3 '). In this case, the air of the heated hollow portion 3 is forced out through the cooling air discharge path 7 formed by the clearance of the hollow portion 3 to the outside, and the cooling air is sprayed onto the preform P. To improve the cooling rate.

Although the width of the cooling air discharge path 7 forms a clearance as a difference between the inner diameter of the hollow part 3 of the cooling pipe 1 and the outer diameter of the preform P, the cooling pipe body as shown in FIG. The inner wall 3 'of 1) is molded to be the same as the outer diameter of the preform P, and a plurality of exhaust grooves 3a are formed in the outer wall 3' to the distal end in the longitudinal direction, thereby cooling air discharge path 7 Can be formed.

This configuration of the discharge groove (3a), it is possible to obtain a more improved cooling rate by maximizing the contact area between the preform (P) and the main body (2) of the cooling pipe (1).

That is, by expanding the contact area between the injected preform P and the cooling pipe 1, the heat of the preform P is effectively transferred to the main body 2 of the cooling pipe 1, thereby improving the cooling speed of the preform P. It can be done.

In addition, the take-up pipe body 10 of the present invention is composed of the suction pipe 11 and the fixed pipe 12, the interval as a means for accurately maintaining the clearance gap of the suction pipe 11 mounted inside the fixed pipe 12 Retaining ring 30 may be coupled between the fixed tube 12 and the suction pipe 11, the spacing retaining ring 30 to maintain the clearance of the cooling air supply path 14 by equally equalizing the cooling air It is possible to increase the cooling efficiency by guaranteeing the emission.

In addition, by selectively forming the gap holding protrusions 11 'and 12' on the outer circumferential surface of the suction pipe 11 or the inner circumferential surface of the fixed pipe 12, the width of the cooling air supply passage 14 is maintained uniformly, and the compressor ( By additionally discharging the cooling air discharged from 40) it is possible to obtain the additional effect of uniformly cooling the entire preform (P).

The gap holding protrusions 11 'and 12' are formed to have a minimum width of 1 mm or less, and the numbers thereof may also protrude one at a 90 degree angle in four directions, respectively, to supply cooling air. It is suitable to be limited in the extent which can maintain the size of the furnace 14 to the maximum.

Taking out the preform (P) formed in the mold (M) of the injection molding machine by the above means, the cooled P (form) taken out in a heated state in the process of transferring to the cooling transfer device 100 for the next process Cooling by using a heat radiation fin of the cooling pipe, and then to completely cool while passing through the next cooling transfer device (100).

1 is an assembled cross-sectional view of a takeover pipe applied to a conventional extraction device;

Figure 2 is a cross-sectional view of the extraction apparatus applied to the present invention

Figure 3 is an enlarged cross-sectional view of the main part of the present invention;

4A is a cross-sectional view of a turnover body

Figure 4b is a longitudinal cross-sectional view of the turnover body to be applied to the present invention

4 is a cross-sectional view of the main part of the present invention.

5 a, b, c, d is an operating state diagram showing the operating sequence of the present invention

Figure 6 is a cross-sectional view showing another embodiment of the take over pipe applied to the present invention

Figure 7 is a partially enlarged cross-sectional view showing another embodiment of the present invention

Figure 8 is a perspective view of the gap retaining ring applied to the embodiment of FIG.

9 and 10 is a cross-sectional view showing another embodiment of the take over pipe applied to the present invention

[Description of Drawings]

1: take over body 2: main body

3: hollow part 3 ': inner wall

4: radiating fin 5: substrate

7: outside air inlet hole 8: packing

10: take over pipe 11: suction pipe

12: fixed tube 13: intake passage

20: base substrate 21: suction pipe

22: supply line 23: fixing screw

30: spacing ring P: preform

C: Cooling board part T: Taking over part

G: Actuator

Claims (6)

A cooling substrate portion C formed by mounting the same number of cooling pipe bodies 1 on the substrate 5 as the number of preform molding portions formed on the mold M for forming the preform P; and Inserting the inside of the cooling pipe (1) is fitted with a take over pipe 10 for introducing the preform (P) injection-molded in the mold (M) into the inside of the cooling pipe (1), The take-over pipe 10 is composed of a double pipe of the suction pipe 11 and the fixed pipe 12, forming a clearance gap between the suction pipe 11 and the fixed pipe 12 to form a cooling air supply passage (14). , An installation substrate 15 formed through the mounting hole 16 to which one end of the fixing pipe 12 constituting the take over pipe 10 is fixed and sealed to the bush 17; and The installation substrate 15 is mounted on the suction pipe passage 21 for sucking external air through the suction passage 13 of the suction pipe 11 constituting the take over pipe 10 and the cooling air supply passage 14. A take-up part T composed of a base substrate 20 having a supply pipe 22 for supplying cooling air; and An actuating part (G) comprising a rack (25) and a pinion (26) for operating the take-up part (T) in the cooling substrate part (C), and a reverse rotation motor (27) connected to the pinion (26); Preform extraction device for injection molding machine, characterized in that consisting of. The method of claim 1, The cooling pipe body 1 constituting the cooling substrate part C has a plurality of radiating fins 4 radially formed at an outer circumferential edge thereof, and has a cooling air discharge path 7 between the introduced preform P and the inner wall 3 '. Preform take-out device for an injection molding machine characterized in that) formed. 3. The method of claim 2, Preform ejection apparatus for an injection molding machine, characterized in that the cooling air discharge path (7) is formed by forming a plurality of discharge grooves (3a) extending vertically in the inner wall (3 ') of the take over pipe (10). The method of claim 1, Preform ejection device for an injection molding machine, characterized in that the cooling air supply path 14 is formed by protruding the interval maintaining projection (11 ') in the longitudinal direction on the outer peripheral edge of the suction pipe (11) constituting the take over pipe (10). . The method of claim 1, Preform ejection apparatus for an injection molding machine, characterized in that the cooling air supply passage 14 is formed by protruding the gap maintaining projection (12 ') in the inner peripheral edge of the fixed tube (12) constituting the take over pipe (10). The method of claim 1, Both ends of the suction pipe 11 constituting the take over pipe 10 and the fixed pipe 12 are coupled to a space maintaining ring 30 integrally formed with a small support protrusion 31 projecting inwardly to provide a cooling air supply path. A preform ejection device for an injection molding machine, characterized in that the clearance gap of (14) is maintained uniformly.

Images