KR101410018B1 - Flow control device is equipped with hot runner systems of manifold - Google Patents

Abstract

The present invention relates to a manifold of a hot runner system equipped with a flow rate regulating device.
A manifold of a hot runner system provided with a flow rate regulating device includes a manifold having a mounting groove formed therein and provided with a flow rate regulating device connected to the resin flow path and controlling a supply amount of the molten resin to be supplied, The flow rate regulating device includes a communication hole formed to communicate with the resin flow path, a guide groove formed at the lower end of the communication hole, a blocking hole configured to seal the communication hole, and a spring having a fastening flange for fixing the flow rate adjusting device to the manifold. bush; An adjusting pin provided in the guide groove and selectively blocking or opening the resin flow path while moving up and down along the communication hole; A spring provided in the guide groove to provide an elastic restoring force to the adjustment pin; And a screw plug coupled to the cut-off hole, the tool plug having a tool groove into which a tool is inserted for separating the cut-off hole from the rear, the manifold being provided with a flow rate adjusting device.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a manifold for a hot runner system,

The present invention relates to a manifold of a hot runner system equipped with a flow rate regulating device. More particularly, the present invention relates to a method for molding a mold release product by injection molding, and more particularly, to a method of molding a mold release product, To a manifold of a hot runner system equipped with a flow rate regulating device for mass production of a high-quality mold release product by controlling the supply amount of the molten resin to prevent a difference in the supply amount of the resin from being generated.

Generally, a hot runner system is a system in which a sprue and a runner, which serve as a flow path of a molten resin for filling a cavity in a plastic injection mold, are heated and kept in a molten state at all times A valve nozzle system for producing products by selectively opening or closing the gate of a mold core by using a pneumatic or hydraulic valve and sliding the valve pin in the nozzle when injecting and pressing the nozzle, (Open Nozzle System), which is filled with a resin in a state where the resin is melted to the gate of the mold, and sealing the gate by using cooling of the mold, and an open nozzle system sealing the gate by electrical action Short Off System (Shut Off System)

1 is a schematic view of a hot runner system according to the prior art.

As shown in the drawing, the hot runner system according to the prior art includes a manifold 130 including a manifold flow path 132, which is a resin flow path through which the resin is supplied and moved, a manifold 130 connected to the manifold flow path 132, A nozzle 120 installed on the reinforcing plate 104 to discharge the resin supplied to the gate 112 of the cavity plate 102 and a nozzle 120 installed on the manifold 130 to discharge the resin supplied to the gate 112 of the cavity plate 102. [ A valve pin 160 inserted in the inner diameter of the folding line 132 and the inner diameter of the nozzle 120 to selectively open and close the nozzle 120 while lifting the center of the folding line 132, And a cylinder 170 in which a pair of air lines for providing a pressure for raising and lowering the valve pin 160 are formed.

Here, the manifold 130 according to the related art is provided with a heating pipe, which is a heating element, in the manifold 130 in order to prevent the molten synthetic resin from being hardened during resin flow into the cavity of the lower mold.

That is, the normal manifold 130 is formed with a resin flow path, which is a manifold flow path 132 branched into a plurality of branches, inside the resin flow path, in order to maintain stable fluidity while preventing resin from solidifying The heating pipe is a pipe having a circular cross section and has a structure in which a coil-shaped heating wire that exerts heat by supplying electric power to the inside of the heating pipe is provided.

The structure of the conventional manifold 130 includes a branched resin flow path through which the synthetic resin in a molten state moves, and a heater wire disposed around the resin flow path and serving as a heating element for preventing resin solidification, . A nozzle connecting hole connected to the resin flow path for guiding the resin to the nozzle and a resin inflow hole connected to the cylinder for supplying the molten resin to the branched resin flow path are formed.

However, the manifold 130 according to the related art supplies molten resin through a plurality of branching resin flow paths in order to injection-mold the mold release products or simultaneously form one set of other products. At this time, The supply amount of the molten resin supplied varies and the quality of the product to be delivered deteriorates.

Korean Patent No. 0931799 (December 4, 2009)

In order to solve this problem, in order to simultaneously mold other products in one set when injection-molding a mold releasing product, the molten resin supplied to the gate through the resin flow path of the manifold is shifted by a distance The present invention has been made in view of the above problems, and it is an object of the present invention to control the supply amount of the molten resin in order to prevent the difference in the supply amount of the supplied molten resin from occurring.

According to an aspect of the present invention, there is provided a manifold of a hot runner system including a flow rate regulating device, comprising: a manifold having a mounting groove formed therein, the flow rate regulating device being connected to the resin flow path to control a supply amount of the molten resin to be supplied; Wherein the flow rate regulating device includes a communication hole formed to communicate with the resin flow path, a guide groove formed at a lower end of the communication hole, a blocking hole configured to seal the communication hole, and a flow rate adjusting device A spring bush having a fastening flange for fixing the spring bush; An adjusting pin provided in the guide groove and selectively blocking or opening the resin flow path while moving up and down along the communication hole; A spring provided in the guide groove to provide an elastic restoring force to the adjustment pin; And a screw plug coupled to the cut-off hole, the tool plug having a tool groove into which a tool is inserted for separating the cut-off hole from the rear, the manifold being provided with a flow rate adjusting device.

Further, in the present invention, a through hole is formed in the spacer block of the hot runner system in which the manifold is installed, so that a tool can be inserted into the tool groove of the screw plug .

The manifold of the hot runner system according to the present invention is characterized in that the end portion of the through hole is provided with a finishing portion for fastening mood bolts or the like to prevent foreign matter from flowing into the end portion of the through hole.

According to the present invention, the adjusting pin may include a lower supporting portion for supporting a lower end of the spring, a fixing jaw inserted into the screw plug to fix the adjusting pin downwardly protruding therefrom, Wherein the rotary groove is formed in a depressed shape. The manifold of the hot runner system is provided with a flow rate regulating device.

The present invention also provides a manifold for a hot runner system having a flow regulating device, wherein a fixing groove is formed at an upper end of the screw plug, the fixing groove being formed at a lower end of the regulating fin.

Further, in the present invention, a support portion for supporting an upper portion of the spring is formed on an upper end of the guide groove, and a manifold of the hot runner system equipped with the flow rate regulating device is provided.

According to the present invention as described above, there is an effect of preventing a difference in the supply amount of the molten resin to be supplied from being generated while the molten resin supplied to the gate through the resin flow path of the manifold differs in the distance between the resin flow path and the gate.

Further, according to the present invention, there is an effect that the supply amount of the molten resin is adjusted to supply the molten resin smoothly, thereby mass production of the high-quality releasing product.

1 is a schematic illustration of a hot runner system according to the prior art,
2 is a view illustrating a manifold of a hot runner system equipped with a flow rate adjusting device according to a preferred embodiment of the present invention,
3 is a perspective view illustrating a flow rate control apparatus according to a preferred embodiment of the present invention.
FIG. 4 is an assembled cross-sectional view illustrating a flow rate control apparatus according to a preferred embodiment of the present invention,
5 and 6 are views showing a manifold provided with a flow rate regulating device according to a preferred embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 2 is a view showing a manifold of a hot runner system equipped with a flow rate adjusting device according to a preferred embodiment of the present invention, FIG. 3 is a perspective view showing a flow rate adjusting device according to a preferred embodiment of the present invention, FIGS. 5 and 6 are views showing a manifold provided with a flow rate regulating device according to a preferred embodiment of the present invention.

As shown in the figure, the manifold 230 of the present invention is provided with an inlet hole 232 for supplying the molten resin to the gate when the molten resin is supplied from the inlet hole 232 through which the molten resin flows in communication with the nozzle locator, And a resin supply hole 236 is formed at an end of the water path 234 to be connected to the gate.

The manifold 230 is provided with a heating member 240 which is formed outside the resin flow path 234 to realize a thermal balance between the whole of the resin flow path 234 and maintain the temperature of the molten resin constant .

An installation groove 238 is formed on one side of the manifold 230 to provide a flow rate regulating device 210 connected to the resin flow path 234 to control the supply amount of the molten resin to be supplied.

The flow rate regulator 210 includes a spring bush 310, an adjusting pin 320, a spring 330, and a screw plug 340.

The spring bush 310 is inserted into the installation groove 238 formed in the manifold 230 and connected to the resin flow path 234.

The spring bushing 310 serves as a housing of the flow rate regulating device 210. The regulating fin 320 selectively blocks the resin flow path 234 by an elastic force so that the supply amount of the molten resin to be supplied can be adjusted A communication hole 312 communicating with the resin flow path 234 and into which the adjustment pin 320 is slidably inserted is formed.

The adjustment pin 320 is moved up and down at a lower end of the communication hole 312 of the spring bushing 310 to provide a predetermined elastic force to block or open the resin flow passage 234 along the communication hole 312. [ A guide groove 314 is formed in which a support portion 414 for supporting the upper end of the spring 330 is formed.

On the lower side of the guide groove 314 is formed a thread on the inner periphery so as to prevent the adjustment pin 320 from coming off and to tighten the screw plug 340 to seal the resin flow path 314 and the communication hole 312 A blocking hole 318 is formed.

The outer peripheral surface of the lower end of the spring bushing 310 is formed with a fastening flange 316 to which the fastening means is fastened to the manifold 230 in order to fix the flow control device 210.

The adjustment pin 320 is inserted into the communication hole 312 of the spring bushing 310 and is selectively lifted and lowered along the inner periphery of the communication hole 312 to selectively block the resin flow passage 234 connected to the communication hole 312 Or < / RTI >

The adjustment pin 320 has a lower end supporting portion 322 for supporting the lower end of the spring 330 on the lower outer circumferential surface.

That is, the adjusting pin 320 moves while compressing the spring 330 while supporting the lower end of the spring 330 provided in the guide groove 314, thereby blocking the resin flow path 234, And when it is lowered, the resin flow path 234 is opened while being downwardly moved through the elastic restoring force of the compressed spring 330.

A lower end of the adjusting pin 320 is formed with a fixing protrusion 324 protruding downward to be inserted into a screw plug 340 to be described later to fix the adjusting pin 320. A center pin of the fixing pin 324, A rotation groove 326 for rotating the rotor 320 is formed.

Here, the rotary groove 326 may have a hexagonal groove such that a screw thread is formed on the inner periphery, or a tool such as a hexagonal wrench is inserted.

In this adjustment pin 320, a tool is inserted into the rotation groove 326, and the up and down operation is performed through the rotation of the tool.

The adjustment pin 320 and the screw plug 340 to be described later are integrally coupled to each other through the fixing groove 324 and the fixing groove. When the tool is inserted into the tool groove 342 formed in the shape of the tool, the adjusting pin 320 is pushed to rotate so that the tool can be lifted up. When the screw plug 340 is unscrewed, will be.

The spring 330 is provided in a guide groove 314 formed in the inner periphery of the spring bushing 310. The spring 330 has a support portion 414 formed at an upper end of the guide groove 314, And upper and lower ends are respectively supported through the support portion 322 to provide an elastic restoring force to the adjustment pin 320. [

The screw plug 340 is coupled to the blocking hole 318 formed in the spring bushing 310 and has a fixing groove at the upper end thereof for fixing the fixing pin 324 formed at the lower end of the adjusting pin 320.

At the rear of the screw plug 340 is formed a tool groove 342 into which the tool is inserted so that the screw plug 340 coupled to the cutoff hole 318 is rotated to move the adjusting pin 320 up and down.

The spacer block 202 of the hot runner system in which the manifold 230 is installed is inserted into the tool groove 342 of the screw plug 340 on the same center line as the tool groove 342 of the screw plug 340 A through hole 204 is formed through the spacer block 202 so that the screw plug 340 can be separated from the spring bushing 310. The end of the through hole 204 prevents foreign substances And a finishing portion 206 to which a mild bolt or the like is fastened.

The flow rate control device 210 of the present invention removes the mud bolts fastened to the finishing portion 206 formed at the end of the through hole 204 of the spacer block 202, And the screw plug 340 of the flow rate regulator 210 is rotated to enable the adjustment pin 320 to move up and down.

In order to simultaneously mold other products in one set when the mold release product is injection molded, the molten resin supplied to the gate through the resin flow path of the manifold 230 is separated from the resin flow path 232 by a distance In order to prevent a difference in the supply amount of the supplied molten resin from occurring, it is an invention capable of mass production of a high-quality release product by controlling the supply amount of the molten resin.

The foregoing description is merely illustrative of the technical idea of the present invention and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas falling within the scope of the same shall be construed as falling within the scope of the present invention.

202: spacer block 204: through hole
206: Finishing portion 230: Manifold
310: spring bush 312: communication hole
314: guide groove 316: fastening flange
318: Blocking ball 320: Adjusting pin
322: lower support part 324:
326: rotation groove 330: spring
340: screw plug 342: tool groove

Claims (6)

In a manifold of a hot runner system equipped with a flow rate regulating device,
And a manifold having an installation groove connected to the resin flow path and provided with a flow rate adjusting device for controlling a supply amount of the molten resin to be supplied,
The flow rate regulating device
A communication hole formed to communicate with the resin flow path, a guide groove formed at the lower end of the communication hole, a blocking hole configured to seal the communication hole, and a fastening flange for fixing the flow rate adjusting device to the manifold, A spring bush having a support portion for supporting an upper portion of the spring;
An adjusting pin provided in the guide groove and selectively blocking or opening the resin flow path while moving up and down along the communication hole;
A spring provided in the guide groove to provide an elastic restoring force to the adjustment pin; And
A screw plug coupled to the cut-off hole and having a tool groove into which a tool is inserted for separating the cut-off hole from the rear;
And a flow regulating device including the flow control device.
The method according to claim 1,
Wherein a through hole is formed in the spacer block of the hot runner system in which the manifold is installed so that a tool can be inserted into the tool groove of the screw plug.
3. The method of claim 2,
And a finishing portion to which a mood bolt or the like is fastened is formed at an end portion of the through hole so as to prevent foreign matter from flowing into the end portion of the through hole.
The method according to claim 1,
The adjusting pin has a lower supporting portion for supporting the lower end of the spring and a fixing jaw inserted into the screw plug to fix the adjusting pin and protruding downward. A rotation groove for rotating the adjusting pin is formed at the center of the fixing jaw A manifold of a hot runner system with a flow control device.
The method according to claim 1,
Wherein a screw groove is formed at an upper end of the screw plug to fix a fixing jaw formed at a lower end of the adjusting pin.
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