KR200364202Y1 - Coolant distributing device - Google Patents

Abstract

The present invention relates to a cooling water distributor, and a holder connected to the cooling tank to the cooling water inlet, a main flow passage connected to the holder and a plurality of distribution passages connected to each other vertically and symmetrically to the main flow passage, and elbows connected to the respective distribution passages. It relates to a cooling water distributor consisting of a cooling hose coupled to the elbow to supply the cooling water introduced into the distribution path to the cooling hole formed in the mold. The present invention has the advantage that it is possible to harden the coupling of the cooling hose and the cooling water distributor using the elbow, and to shorten the mold replacement time by easily connecting the cooling hose when replacing the mold during injection molding.

Description

Cooling water distributor {COOLANT DISTRIBUTING DEVICE}

The present invention relates to a cooling water distributor, and more particularly, a holder connected to a cooling tank, a main flow passage connected to the holder, and a plurality of distribution passages each connected to the holder horizontally and symmetrically to the main flow passage and the respective distribution passages. It relates to a cooling water distributor comprising an elbow connected to the elbow and a cooling hose coupled to the elbow to supply the cooling water introduced into the distribution furnace to the cooling holes formed in the mold.

In general, injection molding injects molten resin into a mold and solidifies the molten resin after a certain period of cooling to produce a product. In this injection molding, cooling water is used to uniformly solidify all parts of the molten resin injected into the mold. Supply the mold evenly.

In recent years, due to the enlargement of the product, the portion to which the cooling water must be supplied increases, and thus, an apparatus for distributing and supplying the cooling water to each of the cooling holes in the cooling tank is needed to supply the cooling water to the plurality of cooling holes formed in the mold. Was done.

As such, a device for distributing and supplying cooling water to a plurality of cooling holes is a cooling water distributor. The cooling water distributor generally uses a distributor having a plurality of flow paths or connects a hose directly to the nipple.

However, when the hose is directly connected to the conventional nipple, as the number of cooling holes formed in the mold increases, the number of cooling hoses to be connected to the cooling holes of the mold increases, and when the mold moves after the molten resin is solidified. The entanglement of the cooling hoses occurs, damage of the cooling hose connected between the cooling water distributor and the mold, and it is difficult to remove the cooling hose from the cooling water distributor and the mold.

In addition, in the case of using a distributor having a plurality of flow paths, the cooling hose is connected to a distribution path provided in the distributor by a coupling means such as a nipple. The coupling by the nipple has a strong coupling force, but the cooling hose is replaced in the nipple. When the sealing tape is wound around the nipple to be fixed to the thread formed on the dispenser has a problem that takes a lot of time.

In addition, by controlling the coolant inflow and outflow with one coolant distributor, there is a problem in that the coolant flowing into the mold is partially heated by the coolant that cools the mold, thereby lowering the overall cooling efficiency.

The present invention was devised to solve the above problems, by combining the cooling hose to the rotatable elbow so as not to entangle the cooling hose coupled to the mold, the cooling hose of the cooling hose when the mold is moved after the solidification of the molten resin The present invention provides a coolant distributor that prevents entanglement and damage of the cooling hose connected between the coolant distributor and the mold.

Another object of the present invention is to provide a cooling water distributor using an elbow to facilitate the coupling of the cooling hose and the cooling water distributor to reduce the connection time.

Still another object of the present invention is to install an inlet cooling water distributor for controlling the inflow of cooling water and an outlet cooling water distributor for controlling the outflow of the cooling water, respectively, to prevent the cooling water flowing into the mold from being heated by the cooling water flowing out of the mold. To provide an efficient cooling water distributor.

1 is a perspective view of a cooling water distributor according to the present invention,

2 is a configuration diagram of an embodiment of the elbow and the cooling hose which is a component of the cooling water distributor according to the present invention,

3 is a coupling diagram in which the coolant distributor according to the present invention is mounted in a mold.

<Description of main parts of drawing>

10-Holder 22-Main Euro

23-Distribution path 24-Leak prevention tap

26-Mold joint 30-Mold fixing pin

40-Elbow 41-Stopper

42-Spring 43-Bracket

45-socket 50-cooling hose

51-Plug 60-Sangoa

61-Inlet cooling water distributor 70-Hacoa

71-Outflow cooling water distributor 80-Cooling hole

In order to achieve the above object, the cooling water distributor according to the present invention includes a holder into which cooling water is introduced from the cooling tank, a main flow passage connected to the holder, and a plurality of distribution passages bilaterally symmetrically perpendicular to the main flow passage. And an elbow each opening connected to each of the distribution paths to form a predetermined angle to change the moving direction of the cooling water, and a cooling hose coupled to the elbow to move the cooling water to the cooling hole formed in the mold. It features.

Another feature of the present invention, one end of the elbow is wrapped around the outer circumferential surface of the elbow is provided with a bracket which is movable up and down and a stopper to move in and out of the bracket and a spring to help the vertical movement of the bracket, A groove is formed at one end of the cooling hose.

Another feature of the present invention is that the mold coupler formed between the main passage and the distribution passage, and a mold fixing pin for penetrating the mold coupler to fix the cooling water distributor to the mold.

Another feature of the present invention is an inlet cooling water distributor in which the cooling water supplied from the cooling tank flows into the mold, and an outlet cooling water distributor in which the cooling water passing through the mold is discharged from each other so that the upper and lower cores of the mold are spaced apart from each other. Each will be installed.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 shows the configuration of the cooling water distributor according to the present invention, the cooling water distributor according to the present invention, the holder 10, the flow path connected to the holder 10, the cooling water inlet and the cooling water distributor in the cooling tank, The mold coupler 26 for fixing to the mold, the mold fixing pin 30 penetrating the mold coupler 26, the elbow 40 connected to the flow path, and the elbow 40 are coupled to each other. It consists of a cooling hose 50 for supplying the cooling water introduced from the cooling tank to the cooling hole 80 formed in the mold.

The holder 10 is connected to a cooling tank in which cooling water is stored, and is formed of a general pipe fitting into which cooling water flows into a flow path.

The flow passage is composed of a main flow passage 22 connected to the holder 10 and formed of a pipe through which cooling water passes, and a plurality of distribution passages 23 branched from the main flow passage 22.

The distribution passage 23 is formed as a tube having a space through which the coolant can pass, and is formed symmetrically perpendicular to the main flow passage 22.

The mold coupler 26 is installed between the main flow passage 22 and the distribution passage 33, and is formed as a tube having both sides opened for coupling the mold and the cooling water distributor.

In addition, it is preferable that two or more mold couplers 26 are formed in a diagonal direction to each other so that the cooling water distributor is firmly coupled to the mold.

The mold fixing pin 30 is formed of a rod for passing the mold coupler 26 to fix the cooling water distributor to the mold. Preferably, the male thread is fixed to the mold fixing pin so that the cooling water distributor is firmly coupled to the mold. It is formed in 30, the female acid is formed in the mold coupler (26).

The elbow 40 is a kind of pipe fitting, which is used to connect the pipes to be angled to each other, is usually formed in a 90 ° angle and open both sides, the direction of the coolant flowing out of the distribution path (23) It can be rotated in the state coupled to the distribution path 23 in the vertical direction to improve the directionality of the cooling hose 50 to be described later.

At this time, the elbow 40 may be formed in various ways as a general elbow, as an example, as shown in Figure 2, the outer circumferential surface of the elbow 40 is wrapped around one end of the elbow 40 is possible to move up and down It comprises a bracket (43), a stopper (41) which moves in and out of the bracket (43), and a socket portion (45) consisting of a spring (42) to assist the vertical movement of the bracket (43). desirable.

The cooling hose 50 is a tubular hose connecting the cooling water distributor and the mold. Preferably, the cooling hose 50 is made of nylon 66, which is a synthetic resin having good flexibility and strong heat resistance at high temperature. The nylon 66 has a melting point of 250 ° C. or higher, and thus has high heat resistance, thereby cooling the mold and preventing damage to the cooling hose caused by the temperature of the heated cooling water when the heated cooling water passes through the cooling hose 50.

In addition, the cooling hose 50 preferably includes a plug 51 having a groove in which the stopper 41 is seated at one end of the cooling hose 50 in order to be easily coupled with the socket 45. .

Hereinafter, the action of supplying the cooling water to the mold by coupling the cooling water distributor of the present invention to the mold.

Figure 3 is equipped with a cooling water distributor of the present invention to a mold used for injection molding. An outflow cooling water distributor (71) spaced apart from the inlet cooling water distributor (61) into which the coolant is introduced into the upper core (60) of the mold and the inlet cooling water distributor (61) to cool the mold, and the outlet cooling water distributor (71) to flow out into the cooling water tank (71). ) Is mounted to the mold fixing pin 30 to penetrate the mold coupling hole 26 so as to be coupled to the mold, and the inlet cooling water distributor 61 and the outlet cooling water distributor (also like the upper core 60) in the hacoa 70. 71).

After that, the elbow 40 and the cooling hose 50 are generally coupled by pushing the cooling hose 50 into the elbow 40.

In addition, when using the elbow 40 provided with the socket portion 45 described above, the bracket 43 provided is flipped back and the plug 51 provided at one end of the cooling hose 50 is connected to the elbow 40. Push into the opening.

Then, when the plug 51 pushes the stopper 41 provided on the elbow 40 toward the bracket 43 and the stopper 41 approaches the groove formed in the plug 51, the stopper ( 41 is seated in the groove, the bracket 43 is released and returned to its original position by the force of the spring 42, and the stopper 41 is seated in the groove so that the cooling hose 50 and the elbow 40 are coupled to each other. do.

The elbow 40 is rotated to adjust the direction of the holder 10 and the cooling hose 50 of each of the cooling water distributors in parallel. At this time, the inlet cooling water distributor 61 and the outlet cooling water distributor 71 are preferably installed symmetrically on both sides of each core.

Thereafter, the elbow 40 is connected to one end of the main flow passage 22 not connected to the holder 10 in the inlet cooling water distributor 61, and then the cooling hole 80 is connected to the elbow 40. The cooling hose 50 is not connected, and a valve capable of removing air is connected to the cooling hose to remove microbubbles inside the inlet cooling water distributor 61.

When the removal of the microbubble is completed, when the bracket 43 of the elbow 40 connected to the valve is flipped back and the cooling hose 50 is removed from the elbow 40, the stopper 41 is recessed in the groove. Moving toward 43, the cooling hose is removed from the elbow 40. Thereafter, one side of the leakage preventing tab 24 is engaged in order to control the entry and exit of the cooling water.

When the above process is completed, the preparation process for supplying the cooling water of the cooling water distributor is completed, and injection molding is started.

The molten resin melted at a high temperature is injected into the mold formed in the upper core 60 and the hacoa 70, and has a cooling period of a predetermined period.

At this time, the cooling water from the cooling tank is introduced into the inlet cooling water distributor 61, the cooling water introduced into the inlet cooling water distributor 61 is each distribution path 23 along the main flow path 22 of the inlet cooling water distributor 61. ) And flows into the upper core 60 and the hacoa 70 along the cooling hose 50 whose direction is determined by the elbow 40 connected to the distribution path 23.

Then, the cooling water moves to the cooling hole 80 through the cooling hoses 50 connected to the plurality of cooling holes 80 formed in the upper core 60 and the hacoa 70, respectively. It flows into the inside of the hacoa 70 and cools the molten resin injected into the molds of the cores.

The cooling water circulating in the mold and cooling the molten resin is collected in the outflow cooling water distributor 71 through the cooling hole 80 formed on the opposite side of the cooling hole 80 into which the cooling water flows, and the outflow cooling water distributor ( It flows out into the cooling tank through the holder 10 of the 71.

At the end of the cooling period, the upper core 60 and the hacoa 70 are separated to form a molded product. The holders 10 of the cores and the cooling water distributor are horizontally connected to each other when the mold moves. 10 does not touch the outside, and the cooling hoses 50 mounted on the upper core 60 and the lower core 70 are parallel to the core so that there is no locking phenomenon during the vertical movement of each core.

The present invention is not limited to the technical spirit of the specific embodiments or drawings described above, anyone who has ordinary knowledge in the technical field to which the present invention belongs without departing from the spirit of the present invention claimed in the claims. Of course, various modifications can be made, as well as such variations are within the scope of the present invention.

The unique effect according to the constitution of the present invention is that the cooling hoses coupled to the mold can be arranged not to be entangled, thereby reducing the entanglement of the cooling hoses when the mold is moved after the solidification of the molten resin, which is connected between the cooling water distributor and the mold. This is to prevent damage to the cooling hose.

Another effect of the present invention is to use an elbow to reduce the connection time by facilitating the coupling of the cooling hose and the cooling water distributor.

Another effect of the present invention is to install the inlet cooling water distributor for controlling the inlet of the coolant and the outlet cooling water distributor for controlling the outlet of the cooling water, respectively, in the mold to prevent the cooling water flowing into the mold due to the cooling water flowing out of the cooling efficiency To be good.

Claims (4)

In the cooling water distributor for supplying the cooling water stored in the cooling tank to the mold used for injection molding, A holder into which the coolant flows from the cooling tank, a main flow passage connected to the holder, a plurality of distribution passages bilaterally symmetrically perpendicular to the main flow passage, and connected to each of the distribution passages to change the movement direction of the cooling water; Cooling water distributor comprising a tubular elbow each opening is a predetermined angle, and a cooling hose coupled to the elbow to move the cooling water to the cooling hole formed in the mold. The method of claim 1, One end of the elbow is provided with a socket which wraps around the outer circumferential surface of the elbow and is movable up and down, and a stopper for moving up and down the bracket and a spring to help the vertical movement of the bracket. Cooling water distributor characterized in that the plug is provided with a groove formed at one end of the cooling hose. The method according to claim 1 or 2, And a mold fixing pin formed between the main flow passage and the distribution passage, and a mold fixing pin penetrating the mold coupling hole to fix the cooling water distributor to the mold. The method of claim 3, The inlet cooling water distributor in which the cooling water supplied from the cooling tank flows into the mold and the outflow cooling water distributor which collects and discharges the cooling water passing through the mold are spaced apart from each other and are installed in the upper and lower cores of the mold. Cooling water distributor.