KR200160275Y1 - Injection mold - Google Patents

Abstract

The present invention relates to an injection mold having a direct cooling structure for producing a plastic product.

The injection mold having the direct cooling structure sends a predetermined gas in the process of forming the product P having the boss P 'by sending the molten resin to the inside of the mold 11 so as to provide a gas channel inside the product P. In the injection mold of the method of forming G), the product P has a high thermal conductivity penetrating to a predetermined depth while maintaining concentricity with the inside of the boss (P ') in which the gas channel (G) is formed. Direct cooling tank 32 formed on the boss pin 31, the boss pin 31 so that a cooling fluid is supplied to the inside of the boss pin 31 to maintain a uniform cooling rate at the end of the boss pin 31, the inside of the boss pin 31, And it is characterized in that it comprises a pipe 33 disposed in the center of the direct cooling tank 32 to supply and circulate the cooling fluid to the inside of the direct cooling tank (32).

Accordingly, the present invention is to increase the cooling efficiency in the injection mold for producing a thick plastic product by the gas injection method to achieve a uniform cooling, shrinkage defects such as sink marks and strength reduction at the bolted joint There is an effect to prevent the occurrence of.

Description

Injection mold with direct cooling structure

The present invention relates to an injection mold for manufacturing a plastic product, and more particularly, in the injection mold for manufacturing a thick product by the gas injection method to increase the cooling efficiency to prevent the occurrence of product defects direct cooling structure It relates to an injection mold having.

In general, an injection mold is a device for completing a material such as a thermosetting resin or thermoplastic resin into a molded article of various forms, and as the mold technology advances, it is possible to manufacture precision parts of advanced equipment as well as simple parts such as case cylinders of various machinery. It is also possible.

Figure 1 is an exemplary view showing a state configuration of the main part of the conventional injection mold.

The injection mold 10 is composed of a pressurizing portion composed of a plasticizing screw 12, a hydraulic cylinder 13, a heater 14, and the like, and a mold 11 having a cavity and a runner. The plasticizing screw 12 receives the operating force of the hydraulic cylinder 13 when the pre-melt resin stored in the hopper 15 is melted by the heater 14 and receives the molten resin from the cavity 11 of the mold 11 through the nozzle 16. Pressurized by the supply, which is called the filling step of the pressure supply step. After the cavity is filled with molten resin and subjected to a packing step to compensate for volume shrinkage when it is turned into a solid state, a cycle is completed after the cooling step to minimize thermal deformation and complete the product, and the plasticizing screw 12 is Retract to the original position and enter the preparation phase for the next cycle.

On the other hand, in the case of molding a product having a relatively thick product or a section having a severe change in the cross-section of the home appliances, there is a disadvantage that defects occur easily in the product due to uneven cooling after completion of injection. With reference to FIG. 2A, a sleeve pin guided by a sleeve pipe 21 when a boss P 'formed with a female screw for fastening a bolt, such as a case of a home appliance, is at a point on a product P, 22) is heated during molding of the product P, so that a uniform cooling rate is not maintained and a sink mark S is generated. Although the indirect cooling tank 18 mounted close to the boss P 'is used, it is insufficient to maintain a uniform cooling rate.

In order to prevent such drawbacks, a gas (usually N ₂ gas) during injection may be used in combination to form a hollow article having a thin thickness. As shown in FIG. 1, when a device for supplying a high pressure nitrogen gas into the nozzle 16 through the gas conduit 17 is added, the gas is filled in the thick portion in the above-described filling step to enable uniform cooling. Therefore, the sink mark which is easy to occur during shrinkage is removed.

However, referring to FIG. 2B, when using this method, the gas channel G formed in the thick portion where the product P and the boss P 'are connected is formed relatively long toward the end of the boss P'. Therefore, there is a problem in that the mechanical strength of the boss P 'is reduced and the tightening length L of the bolt is shortened. That is, when the bolt fixing the predetermined part in the home appliance or the like reaches the gas channel G portion of the boss P ', the fastening force is weakened or the boss P' is broken.

Therefore, the present invention is a direct cooling structure to prevent the occurrence of shrinkage defects and decrease in strength of the product by increasing the cooling efficiency in the injection mold for producing a thick plastic product by the gas injection method It is an object of the present invention to provide an injection mold.

1 is an exemplary view showing the main part configuration state of a conventional injection mold.

2a and 2b are enlarged views showing the product forming state using FIG.

3 is an exemplary view showing a device configuration of an injection mold according to the present invention.

<Explanation of symbols on main parts of the drawings>

10: injection mold (conventional) 11: mold

12: plasticizing screw 13: hydraulic cylinder

14: heater 15: hopper

16: nozzle 17: gas conduit

18: indirect cooling tank 21: sleeve pipe

22: sleeve pin 30: injection mold (this invention)

31: Boss pin 32: Direct cooling tank

33: pipe (cooling) S: sink mark

G: Gas channel P: Product

P ': Boss P ": Rib

L: Tightening length

In order to achieve the above object, the present invention is directed to an injection mold in which a molten resin is sent into a mold to send a predetermined gas in a process of forming a product having a boss to form a gas channel inside the product; A boss pin having high thermal conductivity penetrating to a predetermined depth while maintaining concentricity with the inside of the boss in which the gas channel is formed in the product; A direct cooling tank formed on the boss pin such that a cooling fluid is supplied and flowed to the inside near the end to maintain a uniform cooling rate at the boss pin end; And it provides an injection mold having a direct cooling structure characterized in that it comprises a pipe disposed in the center of the direct cooling tank to supply and circulate the cooling fluid to the inside of the direct cooling tank.

EXAMPLE

Hereinafter, with reference to the accompanying Figure 3 will be described in detail a preferred embodiment according to the present invention.

3 is an exemplary view showing a device configuration of an injection mold according to the present invention.

The present invention sends a molten resin to the inside of the mold 11 to send a predetermined gas in the process of forming a product (P) having a boss (P ') to form a gas channel (G) in the product (P) The mold 11 of the injection mold 30 uses the main components of the plasticizing screw 12, the hydraulic cylinder 13, the heater 14, and the like, whereas the mold 11 of the injection mold 30 is used. It further comprises a spin 31 and a direct cooling tank (32).

2A and 2B described above, the present invention relates to a product P in which only a boss P 'on which female threads for fastening bolts are formed is formed. However, in this embodiment, the boss P' is formed with ribs P " It illustrates about the product P supported by the.

At this time, the boss pin 31 according to the present invention is concentric with the inside of the boss (P ') is formed in the gas channel (G) in the product (P) is penetrated to a predetermined depth and then retreat.

The boss pin 31 is reached while maintaining concentricity to a portion where a female screw for fastening the bolt is formed on the boss P 'like the sleeve pin 22 of FIG. 1. The boss pin 31 processed into a cylindrical shape having a hollow portion at the rear moves forward and backward with the mold 11 to complete the boss P 'of the product P.

In addition, according to the present invention, the direct cooling tank 32 is piped so that the cooling fluid is supplied to the inside of the boss pin 31, and the access path of the cooling fluid is divided by the pipe 33 disposed at the center.

The direct cooling tank 32 is a means for cooling the boss P ', the rib P', and the like of the product P, similar to the indirect cooling tank 18 described above, and is an injection product rather than the indirect cooling tank 18. In general, the cooling fluid of the injection mold uses water cooled by using a cooling tower or chiller, and the pipe 33 installed inside the direct cooling tank 32 has such a cooling fluid. As shown by the arrow in the figure to be able to reach smoothly to the inside of the boss pin (31).

On the other hand, the pipe 33 is to be careful not to sharply reduce some of the flow path inside the direct cooling tank 32, when there is a narrowing flow path is easy to accumulate foreign matter, reducing the amount of circulation of the cooling fluid and at the same time cooling It also increases power consumption due to the pumping of the fluid. The boss pin 31 may be uniformly cooled by the direct cooling tank 32 having the pipe 33.

At this time, the boss pin 31 is characterized in that using the Be-Cu alloy material having high thermal conductivity.

The boss pin 31 is preferably a Be-Cu alloy of high thermal conductivity material so that heat exchange between the cooling fluid passing through the direct cooling tank 32 and the boss P 'of the product P is rapid. Therefore, the cooling efficiency is increased compared to the conventional sleeve pipe 21, sleeve pin 22, indirect cooling tank 18 shown in Figures 2a and 2b.

By using the direct cooling tank 32 and the indirect cooling tank 18 as in the present invention, after injection, uniform cooling is induced in all parts of the product P including bosses P 'and ribs P'. There is an advantage that the sync mark S as shown in Figure 2a does not occur.

In particular, the quenching action by the direct cooling tank 32 reduces the penetration of the gas to be supplied, thereby preventing the gas channel G from spreading, and thus, the fastening length L of the bolt is increased than before, and thus the bolt fastening the component Since it can be inserted as deep as it is, the tightening force on the part is improved.

Meanwhile, in the present embodiment, the boss pin 31 and the direct cooling tank 32 for one boss P 'are illustrated and described, but the boss pins 31 and the number corresponding to the number of bosses P' are different. It is also possible to provide a cooling tank 32 directly and to supply cooling fluid to each. In this case, it is possible to expect a uniform cooling effect as a whole by connecting the pipes individually to each boss position.

The direct cooling tank 32 has a function to prevent non-uniform cooling after the completion of the injection in the case of molding a product having a relatively thick product or a section having a severe change in the cross-section of the home appliances can be widely applied.

Injection mold having a direct cooling structure of the present invention according to the configuration and operation described by the above embodiment is to increase the cooling efficiency in the injection mold for producing a thick plastic product by the gas injection method to achieve a uniform cooling In addition, there is an effect of preventing the occurrence of shrinkage defects of the product, such as sink marks, and the strength decrease in the bolt fastening portion.

Although the present invention has been shown and described in connection with certain preferred embodiments, it can be variously modified and changed without departing from the spirit or the scope of the present invention provided by the following claims. Those skilled in the art can easily know that.

Claims (1)

In the process of forming the product P having the boss P 'by sending the molten resin into the mold 11, a predetermined gas is also sent to form a gas channel G in the product P. To; A boss pin 31 having high thermal conductivity penetrating to a predetermined depth while maintaining concentricity with the inside of the boss P ′ in which the gas channel G is formed in the product P; A direct cooling tank (32) formed at the boss pin (31) such that a cooling fluid is supplied to the inside of the boss pin (31) in order to maintain a uniform cooling rate at the end of the boss pin (31); And a pipe (33) disposed in the center of the direct cooling tank (32) to supply and circulate the cooling fluid to the inside of the direct cooling tank (32). mold.