KR101354186B1 - valve system for injection molding - Google Patents

Abstract

The present invention relates to a valve device for injection molding.
The present invention is configured at the lower side of the manifold, the connecting flange is formed so that the valve device can be installed on the reinforcement plate of the hot runner system, and the resin flow path for guiding the molten resin to the mold, and for fixed coupling with the nozzle tip A nozzle housing in which a fastening part is formed; A nozzle tip fastened to a fastening part of the nozzle housing, the resin flow path extending, and a fixing ring and an insulating disk coupled to an outer circumferential surface thereof; An opening having a shape in which one surface is cut out to be fixedly coupled to an outer circumferential surface of the nozzle tip, and a fixing ring having a sensor fixing groove formed along an inner circumference thereof so that a control sensor for controlling the nozzle heater may be installed therein; And a contact portion made of a titanium material and coupled to the outer circumferential surface of the nozzle tip to make contact with the cavity plate in order to minimize the heat loss of the tip of the nozzle tip, and an insulating disk having an insulating groove formed along the outer circumferential surface thereof. Provided is a valve device for injection molding.

Description

Valve system for injection molding

The present invention relates to a valve device for injection molding. More specifically, it is made of a material such as titanium or ceramic to improve wear resistance and corrosion resistance of the nozzle provided in the hot runner, and uniformly and efficiently heat conduction improves the reliability of the injection molding to reduce the defective rate of the injection molding. It relates to a valve device.

In general, a hot runner system is a spun and a runner that serves as a flow path of a molten resin to fill a cavity in a plastic injection mold, thereby maintaining a molten state at all times. It is a system to inject only products continuously.

This hot runner system uses a pneumatic, hydraulic, etc. valve valve system that produces the product by selectively opening or closing the gate of the mold core by sliding in the nozzle when the valve pin is injected and held. Resin is filled in the molten state to the gate of the open nozzle system to seal the gate using cooling of the mold and the shot off system to seal the gate by electric action at the tip end. And the like.

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 nozzle 120 is provided with a nozzle heater 122 on its outer circumferential surface to maintain the fluidity of the resin, the nozzle heater 122 is composed of a heating wire and an insulator that generates heat by being supplied with power therein, By maintaining the nozzle 120 at a constant temperature under the control of a temperature controller provided outside the mold, the resin passing through the nozzle 120 is melted and maintained at a constant temperature.

That is, the nozzle 120 used in the hot runner system includes a nozzle heater 122 that generates heat at a predetermined temperature in order to allow the resin to be discharged in a fluid state, and at this time, the nozzle heater 122 The heater wire is configured to be wound around the outer circumferential surface of the nozzle 120 in the form of a coil, and the heater wire at this time is heated by the controller provided at the outside of the mold to heat the nozzle 120, so that the nozzle 120 has a constant temperature. It is to maintain the melt at a constant temperature in the nozzle 120 when the resin passes through the nozzle 120.

However, the upper end of the nozzle 120 of the hot runner system according to the prior art is in contact with the side of the reinforcement plate 104, and the lower end is in contact with the cavity plate 102 of the mold so that the temperature of the entire nozzle 120 is changed to this nozzle ( The temperature of the nozzle 120 itself is not uniform due to the temperature difference between the mold 120 and the mold, and the heat distribution of the manifold 130 may also be affected by the temperature of the nozzle 120 which is relatively lower than that of the manifold 130. There was a problem. In addition, as the upper end of the nozzle 120 is in contact with the reinforcing plate 104, there is a problem that heat loss such as not being delivered while being maintained at a constant temperature until the nozzle tip 124.

However, since the upper part of the nozzle 120 loses heat from the reinforcing plate 104, the temperature of the nozzle 120 is lowered, and the lower part of the nozzle 120 also contacts the mold. Significant heat loss occurs on the side, and the temperature of the nozzle 120 is inevitably lowered.

As a result, the temperature of the other point is excessively increased to solidify the resin or to heat the specific point, and the temperature difference between the top and the bottom of the nozzle 120 is generated by the influence of the reinforcing plate 104 and the cavity plate 102. There was a problem.

In order to solve the above problems, the present invention is made of a material such as titanium, ceramic, etc. to improve the wear resistance and corrosion resistance of the nozzle provided in the hot runner, and the thermal conductivity is made uniformly and efficiently to improve the reliability of the injection molded product to improve the defective rate The purpose is to reduce the

The present invention for achieving the above object is configured on the lower side of the manifold, the connection flange is formed so that the valve device can be installed on the reinforcement plate of the hot runner system, and the resin flow path for guiding the molten resin to the mold, A nozzle housing having a fastening portion for fixedly coupling with the nozzle tip; A nozzle tip fastened to a fastening part of the nozzle housing, the resin flow path extending, and a fixing ring and an insulating disk coupled to an outer circumferential surface thereof; An opening having a shape in which one surface is cut out to be fixedly coupled to an outer circumferential surface of the nozzle tip, and a fixing ring having a sensor fixing groove formed along an inner circumference thereof so that a control sensor for controlling the nozzle heater is built in; And it is made of a titanium material, coupled to the outer circumferential surface of the nozzle tip and the contact portion which makes contact with the cavity plate, and provides an injection molding valve device comprising a heat insulating disk formed with a heat insulating groove along the outer circumferential surface.

In addition, in the present invention, the connecting flange is provided with a valve device for injection molding, characterized in that the lead groove for receiving the heater coil of the nozzle heater and the control sensor for controlling the nozzle heater is formed.

In addition, in the present invention, the nozzle tip is a nozzle heater is formed on the outer periphery, the first tip body and the insertion groove is formed is formed extending from the first tip body, the fastening portion of the nozzle housing is inserted into the outer periphery, According to the present invention provides a valve device for injection molding comprising a second tip body coupled to the fixing ring and the insulating disk in an interference fit manner.

In addition, in the present invention, the second tip body is in close contact with the control sensor provided on the fixing ring to the inner surface of the fixing ring, a fixing protrusion for providing a more rigid fixing force between the second tip body and the fixing ring is formed It provides a valve device for injection molding, characterized in that.

In addition, in the present invention, when the fixing ring is combined with the nozzle tip, the tension groove for injection molding, characterized in that each of the tension grooves are formed in the upper both sides of the opening so that the assembly is easy to provide a predetermined tension Provide a valve device.

According to the present invention, it is made of a material such as titanium, ceramic, etc. to improve the wear resistance and corrosion resistance of the nozzles provided in the hot runner, uniform and efficient thermal conductivity to improve the reliability of the injection molding to reduce the defective rate of the injection molding It can be effective.

1 is a view schematically showing a valve device according to the prior art,
Figure 2 is an exploded perspective view showing a valve device of the injection molding of the present invention,
3a and 3b is a view showing the insulating disk and the retaining ring configured in the valve device of the injection molding of the present invention,
Figure 4 is a cross-sectional view schematically showing a valve device of the injection molding of the present invention,
Figure 5 is another embodiment showing a valve device of the injection molding 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.

Figure 2 is an exploded perspective view showing a valve device of the injection molding of the present invention, Figures 3a and 3b is a view showing an insulating disk and a retaining ring configured in the valve device of the injection molding of the present invention, Figure 4 is a view of the injection molding of the present invention Figure 5 is a schematic cross-sectional view of the valve device, Figure 5 is another embodiment showing a valve device of the injection molding of the present invention.

As shown, the valve device of the present invention is connected to the nozzle housing 210, the nozzle housing 210, which is connected to the manifold 130 to move the molten resin, the end is connected to the gate to the molten resin into a mold It is fixedly coupled to the nozzle tip 220 to supply, the outer circumference of the nozzle tip 220, the fixed ring 230 for fixing the control sensor 202 for controlling the nozzle heater 122 and the outer peripheral end of the nozzle tip 220 It is configured to include an insulating disk 240 coupled to.

The nozzle housing 210 is configured under the manifold 130, and a connecting flange 212 is formed to allow the valve device to be installed on the reinforcement plate 104 configured in the injection molding hot runner system. A resin flow path 218, which is integrally formed with the flange 212 and connected to the resin flow path 132 of the manifold 130, guides the molten resin supplied from the manifold 130 to the mold. .

Here, the connecting flange 212 configured in the nozzle housing 210 is configured at the lower end of the manifold 130, and is configured to be in close contact with the reinforcing plate 104, the molten resin supplied from the manifold 130 is discharged Is configured to prevent.

In addition, the connection flange 212, the heater coil of the nozzle heater 122 for maintaining the temperature of the molten resin supplied to the mold through the resin flow path 218 at a constant temperature and a control sensor for controlling the nozzle heater 122 A lead groove 214 is formed in which the 202 is accommodated.

In addition, an end portion of the nozzle housing 210, that is, an opposite portion of the connection flange 212, includes a fastening part 216 for fixedly coupling to the nozzle tip 220.

The nozzle tip 220 is coupled by fastening with the fastening part 216 formed at the end of the nozzle housing 210, and the resin flow path 218 of the nozzle housing 210 is formed therein and the molten resin is extended. It is formed through so that it can be supplied to the mold.

The nozzle tip 220 is formed to extend to the first tip body 224 and the tip body 224 is securely fastened to the nozzle housing 210, the resin flow path 218 is formed therein And a second tip body 222 to which the fixing ring 230 and the insulating disk 240 are coupled to the outer circumference.

The first tip body 224 is configured such that the nozzle heater 122 surrounds the outer circumference, and the fastening of the nozzle housing 210 therein is made so that the nozzle housing 210 is firmly fastened to prevent the melted resin from leaking out. An insertion groove into which the portion 216 is inserted is formed, and a thread is formed on the inner circumference of the insertion groove to fasten the fastening portion 216.

At this time, the screw thread formed in the first tip body 224 is formed of a female thread, the screw thread formed in the fastening portion 216 is formed of a male screw thread so that the nozzle housing 210 and the nozzle tip 220 through the screw fastening method Is configured to be fastened, it is preferable that a separate sealing member is provided between the first tip body 224 and the fastening portion 216, but is not limited thereto.

The second tip body 222 is configured such that the fixing ring 230 and the insulating disk 240 can be coupled in an interference fit manner along the outer circumference.

The second tip body 222 is inserted into the sensor fixing groove 232 of the fixing ring 230 to be described later, the control sensor 202 provided in the sensor fixing groove 232 is the inner surface of the fixing ring 230 The fixing protrusion (not shown) may be formed along the outer circumference of the second tip body 222 while being in close contact with the second tip body 222 and providing a more firm fixing force between the second tip body 222 and the fixing ring 230. It is not limited to this.

The fixing ring 230 is fixedly coupled to the second tip body 222 of the nozzle tip 220 but coupled through an interference fit method, and an opening having one side cut out to be coupled to the nozzle tip 220. 234 is formed, and the coupling with the nozzle tip 220 through the opening 234. That is, the fixing ring 230 of the present invention may be formed in the shape of approximately "C".

In addition, a sensor fixing groove 232 is formed in the inner circumference of the fixing ring 230 along the inner circumference of the fixing ring 230 so that the control sensor 202 for controlling the nozzle heater 122 is installed therein.

In addition, the fixing ring 230 of the present invention, when coupled with the nozzle tip 220, by providing a predetermined tension, the tension groove 236 is formed so that a more convenient assembly can be formed, the tension groove 236 The openings 234 of the fixing ring 230 are formed on both sides of the upper sides of the openings 234 so that the openings 234 of the fixing ring 230 can be more easily opened while being coupled to the outer circumferential surface of the second tip body 222 of the nozzle tip 220. desirable.

Insulating disk 240 is provided to minimize the heat loss of the tip of the nozzle tip 220, like the fixing ring 230 is coupled to the outer circumferential surface of the nozzle tip 220 by the interference fit method, which is made of titanium material will be.

The insulating disk 240 has a contact portion such that the minimum contact is made with the cavity plate 102 in order to minimize the contact area between the insulating disk 240 and the cavity plate 102 in order to minimize the heat loss of the nozzle tip 220. 244 is formed, and the insulating groove 242 is formed along the outer circumference of the insulating disk 240.

The present invention configured as described above improves the wear resistance and corrosion resistance of the nozzle provided in the hot runner through the insulating disk 240 made of titanium, ceramic, etc. It is possible to reduce the defective rate of the injection molding.

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.

210: nozzle housing 212: connecting flange
214: lead groove 216: fastening portion
218: resin flow path 220: nozzle tip
222: second tip body 224: first tip body
230: fixing ring 232: sensor fixing groove
234: opening 236: tension groove
240: insulation disk 242: insulation groove

Claims (5)

It is configured on the lower side of the manifold, and a connecting flange is formed so that the valve device can be installed on the reinforcement plate of the hot runner system. Nozzle housing;
A nozzle tip fastened to a fastening part of the nozzle housing, the resin flow path extending, and a fixing ring and an insulating disk coupled to an outer circumferential surface thereof;
An opening having a shape in which one surface is cut out to be fixedly coupled to an outer circumferential surface of the nozzle tip, and a fixing ring having a sensor fixing groove formed along an inner circumference thereof so that a control sensor for controlling the nozzle heater may be installed therein; And
It is made of titanium material, and coupled to the outer peripheral surface of the nozzle tip includes a contact portion in contact with the cavity plate in order to minimize the heat loss of the tip of the nozzle tip, and an insulating disk formed with an insulating groove along the outer peripheral surface,
The nozzle tip has a nozzle heater formed on an outer circumference thereof, the first tip body having an insertion groove formed therein by which the fastening portion of the nozzle housing is inserted, and extends from the first tip body, and has a fixed ring and an insulating disk along the outer circumference. Injection valve device comprising a second tip body coupled in an interference fit manner.
The method of claim 1,
And a lead groove in which the connection flange receives a heater coil of the nozzle heater and a control sensor for controlling the nozzle heater.
delete The method of claim 1,
The second tip body is in close contact with the control sensor provided on the fixing ring to the inner surface of the fixing ring, the injection molding, characterized in that the fixing projections for providing a more rigid fixing force between the second tip body and the fixing ring is formed. Valve device.
The method of claim 1,
When the fixing ring and the nozzle tip is coupled to the fixing ring, the tension groove is formed in each of the upper both sides of the opening so as to provide a predetermined tension can be easily assembled valve device for injection molding, characterized in that.

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