KR101289877B1 - hot runner apparatus - Google Patents

Abstract

A hot runner device for use in an injection molding operation is disclosed.
The hot runner device includes a manifold having a runner formed therein so that the molding resin flows from one side to the other side, and heats toward the runner so that the molding resin flows in the molten state inside the manifold. Stirring of the heater part having a heater to be generated, the nozzle part having a nozzle disposed to correspond to one end of the runner and formed to inject the molding resin into the mold side, and stirring of the molding resin flowing toward the nozzle part It includes a raw material stirring portion provided with a stirring port to guide the flow to enable the molding resin is supplied to the nozzle side in a stirred state.

Description

Hot runner apparatus

The present invention relates to a hot runner device that can further improve the supply quality of molding resin.

In general, the hot runner device allows the molding resin to be stably supplied to the mold side through various points in the molten state when the injection molding operation is performed by using the injection molding machine. It is known that molding has the advantage of being possible.

The hot runner apparatus includes a manifold provided with a runner through which the molding resin flows, a heater unit generating heat toward the runner of the manifold, and a molding resin supplied from the runner to be injected into a mold. It consists of a nozzle unit that is installed so that.

According to the structure of such a hot runner device, it is particularly important to uniformly supply the molding resin in the molten state to the cavity side of the mold through the runner section inside the manifold.

However, the above-mentioned conventional hot runner devices are mostly limited to a simple structure for supplying a molding resin in a molten state, and thus, various problems may occur in the injection molding operation.

That is, when the resin for molding flows into the sprue portion corresponding to one end of the runner of the manifold and flows from one side to the other side, so-called laminar flow phenomenon of resin is easily flowed in an irregularly distributed state. May occur. Then, the molding resin may be unevenly injected into the mold, thereby causing excessive defect quality. In particular, as described above, a simple structure for the runner of the manifold to supply the molding resin in a molten state and If limited to the function, for example, when supplying molding resins of different colors, or a variety of additives for improving aesthetics or function with a water support material, it is supplied evenly mixed in the runner section of the manifold There is a limit to this.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems occurring in the prior art,

An object of the present invention is to provide a hot runner device capable of stably supplying a molding resin to a mold side while uniformly stirring the molding resin.

In order to realize the object of the present invention as described above,

A manifold having a runner formed therein so that the molding resin can flow from one side to the other side;

A heater unit having a heater for generating heat toward the runner to allow the molding resin to flow in a molten state inside the manifold;

A nozzle unit disposed to correspond to one end of the runner and having a nozzle configured to inject molding resin into a mold side;

A raw material stirring part provided with a stirring port for guiding the flow of the molding resin flowing toward the nozzle part to supply the molding resin to the nozzle part in a stirred state;

It provides a hot runner device comprising a.

In the present invention as described above, a stirring part (stirrer) is provided at a point corresponding to the runner of the manifold so that the molding resin can be supplied to the mold side in a uniformly stirred state.

In particular, the stirring port is formed so that the stirring can be performed in a manner to guide the flow state of the molding resin in the runner, according to such a stirring structure, while the molding resin flows without having a separate driving source for stirring, etc. The molding resin can be uniformly stirred by a simple stirring action.

Therefore, the present invention can increase the quality of the molding resin during the injection molding operation because the resin can be injected in a uniformly stirred state when injecting the molding resin to the mold side, thereby further improving the molding quality. It can be secured.

1 is a view schematically showing the overall structure of a hot runner device according to an embodiment of the present invention.
2 to 5 are views for explaining the detailed structure and preferred operation of the hot runner device according to an embodiment of the present invention.

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

The embodiments of the present invention will be described by those skilled in the art to which the present invention is applicable.

Therefore, the embodiments of the present invention can be modified into various other forms, so that the claims of the present invention are not limited by the embodiments described below.

Referring to FIG. 1, reference numeral 2 designates a manifold of the hot runner device.

The manifold 2 may be installed at the mold structure M having a laminate structure and having a runner L serving as a passage through which the molding resin R may pass in a molten state.

The mold structure M is, for example, in a conventional structure having a clamping plate M1, a space plate M2, a holding plate M3, and a cavity plate M4 from above, as shown in FIG. 1. The manifold 2 may be provided between the clamping plate M1 and the holding plate M3 spaced apart from each other by the space plate M2.

The manifold 2 may be divided into one or more branches and extended toward the outside so as to form a runner L section corresponding to the cavity C formed on the cavity plate M4 side, for example. It may be made of a structure in the form of a metal block having a.

The material of the manifold 2 may be a metal of, for example, a free hardened steel KP series, among metals having excellent durability and heat resistance.

The manifold 2 may be provided with a positioning pin A1 as shown in FIG.

When the positioning pin (A1) is set to the mold structure (M) side of the manifold (2) to enable the supply of molding resin (R) to the cavity (C) side of the cavity plate (M4). In addition, the nozzle unit 6 to be described later serves to guide (determine) the position of the nozzle unit 6 in a fitting manner so that the nozzle C may be located at a point corresponding to the gates of the cavity C.

In addition, the manifold 2 may be provided with sprues A2 and sprue as shown in FIG. 1.

Although not shown in the figure, the sprue portion A2 serves as a kind of inlet for receiving the molding resin R from the injection machine, and one end of the runner L in the state disposed on the upper side of the manifold 2. It can be installed in communication with.

That is, one end of the runner L is connected in communication with the sprue part A2, and the other side thereof extends to correspond to the extension parts of the manifold 2, and the inside of the cavity C of the cavity plate M4 is extended. It is formed to provide a passage section that can be injected of the molding resin (R).

The hot runner device according to the embodiment of the present invention includes a heater unit 4 and a nozzle unit 6 installed to correspond to the manifold 2.

The heater part 4 is formed to generate heat toward the runner L at the manifold 2 side, and the nozzle part 6 is a molding resin R flowing into the runner L. Is formed to be injected into the cavity C side of the cavity plate M4.

The heater unit 4 may be composed of heaters of the hot wire type, for example, smoothly toward the inside of the runner (L) at one or more points corresponding to the extension section of the runner (L). It may be installed inside the manifold (L) in a state capable of generating heat.

Although not shown in the drawings, the heaters H may be set to control operation (heating) in a conventional manner by a separate controller operation, so that the runner L may maintain a range of about 200 to 400 degrees Celsius. It works.

The nozzle part 6 includes a nozzle N, and one end of the nozzle N is fixed to the lower surface of the manifold 2 so as to correspond to the end of the runner L as shown in FIG. 1. It may be arranged in a standing state to correspond to the cavity C of the cavity plate M4.

The nozzle N has, for example, a nozzle hole N1 communicating therein with the runner L, and the nozzle pin N2 is provided in a direction passing through the nozzle hole N1. The pin N2 may be set to open and close an end of the nozzle hole N1 while the upper end is connected to a driving source N3 such as an actuator and moved upward and downward by the power of the driving source N3. .

On the other hand, the hot runner device according to an embodiment of the present invention, comprises a raw material stirring portion 8 for stirring the molding resin (R).

In particular, the raw material stirring part 8 is disposed at a point corresponding to the runner L to stir while guiding the flow (direction) of the resin to the protrusions or the grooves or the holes while the molding resin R flows. It is formed to be.

The stirring port (B), as shown in Figure 1 may be provided to enable the stirring of the molding resin (R) in the nozzle (N) of the nozzle (6).

Referring to FIG. 2, the stirring port B may be formed in a cylindrical type that may be fitted into the nozzle N, and the first guide part B1 to the second guide part B2 as shown in the drawing. It can be made, including).

The first guide portion B1 may be formed to guide the flow of the molding resin R in a curved (or straight) shape, and the second guide portion B2 may be in a branched state. It may be formed to guide the flow of the molding resin (R).

For example, the first guide part B1 is formed of guide protrusions G1 extending in a spiral shape from one side of the outer surface of the stirring hole B toward the other side of the molding resin R. The flow may be formed to proceed while being guided in a spiral shape.

The first guide part B1 may have a curved (spiral) shape in addition to the structure that is guided, for example. (N1) It may be formed of protrusions or grooves formed to guide the resin flow in a straight line direction of the twisted or inclined state to either side from the central axis of the inside.

That is, the first guide part B1 guides the molding resin R flowing along the runner L to flow in a direction different from the flow direction of the runner L. FIG.

The second guide part B2 is formed by forming a plurality of guide holes G2 formed in a straight line (or oblique line) in a direction along the direction in which the molding resin R flows on the stirring hole B. The resin R may be formed to flow while being guided in a branched state by the guide holes G2.

That is, the second guide part B2 guides the molding resin R flowing in one stem along the runner L so as to flow in several branches.

The second guide part B2 provides a structure in which the molding resin R flows while passing through the guide holes G2. For example, the second guide part B2 is not shown in the drawings, but the various types of resins included in the molding resin R are included. It also acts as a filter to filter out solid debris.

In general, the molding resin (R) is known to contain some of the solid foreign matter in the recycled resin, it is possible to easily hang the solid foreign matters when using the recycled resin.

The stirring port B may further include a third guide part B3.

In particular, the third guide portion B3 is formed such that the molding resin R is guided in a vortex or turbulent flow.

The third guide portion B3 is approximately hemispherical on the outer surface corresponding to the direction in which the molding resin R flows in, for example, as shown in FIG. It may be made of a guide groove (G3) dug into the shape.

That is, the third guide part B3 guides the molding resin R to flow in a direction different from the guide direction of the first guide part B1.

In addition, the guide groove G3 of the third guide part B3 may be provided between the first guide part B1 and the second guide part B2 as shown in FIG. 2.

Then, the molding resin R having passed through the first guide part B1 flows in a vortex or turbulent atmosphere by the third guide part B3 in the same direction as in FIG. 2. While being guided to have a second guide portion (B2) can be supplied to the side can further enhance the stirring effect.

The third guide portion B3 is not limited to the structure consisting of the guide groove G3 as described above. For example, although not shown in the drawings, the molding resin R may have a protrusion structure that can be smoothly guided to have a vortex or turbulent flow.

As described above, the stirring port B includes the first guide part B1, the second guide part B2, and the third guide part B3 as shown in FIG. In accordance with this can be made to include one or more guides to enable a stirring action corresponding thereto.

The stirring port B may use, for example, the same material as that of the manifold 2, that is, a SUS-based metal, among metals having excellent durability and heat resistance.

The stirring port (B) may be fixed inside the nozzle hole (N1) by fitting, for example, so as not to move when installed in the nozzle (N), the nozzle pin (N2) is shown in Figure 1 and As shown in Figure 2 is set through the center portion of the stirring port (B) is set to the engaging state capable of opening and closing operation in the vertical direction.

According to the structure of the stirring unit 8, the molding resin R flowing along the runner L of the manifold 2 may be stirred when passing through the inside of the nozzle unit 6.

That is, as shown in FIG. 3, when the molding resin R introduced into the nozzle N through the runner L of the manifold 2 passes through the stirring port B, the first guide. The flow state may be guided in a spiral shape by the guide protrusion G1 of the part B1.

As described above, the molding resin R guided to the first guide part B1 is provided by the third guide part B3 as shown in FIG. 4 before being supplied to the second guide part B2 side. It is guided to have a vortex or turbulent flow in the same direction.

In addition, the molding resin R guided by the third guide part B3 is divided into two or more parts by guide holes G2 of the second guide part B2 as shown in FIG. 4. It can be guided to flow in the shape of being divided.

According to the action of the raw material stirring portion 8, when the molding resin (R) is supplied through the runner (L) by the guides (B1, B2, B3) of the stirring port (B) The resin can be uniformly stirred by a stirring method that guides the flow of the molding resin R in a direction different from the flow direction of (L) or diverged into several branches.

Therefore, in the present invention, since the molding resin R can be supplied in a uniformly stirred state before being injected into the cavity plate M4 side, for example, the molding resin R is simply supplied and injected, although not shown in the drawing. Compared with the conventional hot runner devices that are limited to the structure to increase the quality of the molding resin (R) it can ensure a more improved molding quality.

In the above description, the raw material stirring part 8 is provided on the nozzle part 6 side as an example and shown in the drawings. However, the present invention is not limited to this structure, and in addition, it corresponds to the runner L so as to meet the work requirements. It can be properly installed at one or more points.

For example, as shown in FIG. 5, the stirring port B is installed at two points corresponding to the runner L section of the manifold 2 to stir at two points during the movement of the molding resin R. This may be done, but in addition to the above, although not shown in the drawings, the stirring holes B may be appropriately installed at three or more points.

2: manifold 4: heater part 6: nozzle part
8: Raw material stirring part L: Runner B: Stirring hole
B1: first guide B2: second guide B3: third guide

Claims (7)

delete delete delete delete delete delete A manifold having a runner formed therein so that the molding resin can flow from one side to the other side;
A heater unit having a heater for generating heat toward the runner to allow the molding resin to flow in a molten state inside the manifold;
A nozzle unit disposed to correspond to one end of the runner and having a nozzle configured to inject molding resin into a mold side;
A raw material stirring part having a stirring hole for stirring the molding resin flowing toward the nozzle part in a different flow state at a point corresponding to the runner;
Including;
The stirring sphere,
A first guide part formed of a guide protrusion or a guide groove formed so that the molding resin flowing from one side to the other side is guided by a flow passing in a spiral shape;
Molding resins disposed on one side of the first guide part and flowing from one side to the other side are divided into one or more branches and formed to be guided in a flow passing in a branched shape in a straight or diagonal direction. A second guide portion formed;
A third guide part formed of a guide groove or a guide protrusion formed to be supplied while being molded into the flow causing the vortex toward the second guide part;
Hot runner device comprising a.

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