KR100659731B1 - Molten resin feeder for injection molding machine - Google Patents

Abstract

The present invention relates to a device for supplying the molten resin in the supply device for supplying the molten resin to the mold in the injection molding machine, more specifically, the molten resin is smoothly supplied regardless of the thermal expansion of the manifold according to the supply of the molten resin Of course, in order to be able to enlarge the supply of molten resin,

Injection molding in which the molten resin supplied from the injection machine is intermittently supplied by the operation cylinder with a manifold having a supply passage, an injection nozzle with an injection hole, and a nozzle pin inserted through the manifold into the injection hole of the injection nozzle. An apparatus for supplying a molten resin, comprising: a flow space portion formed to be spaced a predetermined distance between an outer surface of a nozzle pin inserted through the manifold and an inner surface of the manifold; An auxiliary supply path formed such that the molten resin supplied to the injection nozzle through the supply path is supplied to the injection hole from the upper surface of the body of the injection nozzle through an inner outer side; The upper portion of the injection hole is formed with a support for supporting the nozzle pin is inserted, the support body is formed integrally formed on the upper surface of the body formed with the support, the insertion groove into which the guide support is inserted into the corresponding manifold And a second flow space portion between the guide support and the insertion groove, and the guide support is inserted into the bottom of the guide support and engages the support bush inserted into the nozzle pin from the top of the manifold. And a third flow space portion formed between the support bush and the inner surface of the manifold.

Description

Apparatus for supplying melting resin using injection molder}

1 is a front sectional view showing main parts schematically showing the present invention.

2 is an enlarged cross-sectional view of the main portion of part A according to FIG. 1;

Figure 3 is a sectional view schematically showing the main portion of another embodiment of the present invention.

Figure 4 is a sectional view schematically showing the main portion of another embodiment of the present invention.

5 is a sectional view showing principal parts of still another embodiment of the present invention;

Figure 6 is a main sectional front view schematically showing a conventional molten resin supply apparatus of the injection molding machine.

Explanation of symbols for the main parts of the drawings

10: flow space part

20: auxiliary supply

   20a: ramp 22: funnel

   24: By connection

30: support part

   32: guide support portion 34: insertion groove portion

   36: second flow space portion

40: support bush

   42: third flow space portion

110: manifold

   112: supply path

120: injection nozzle

   122: injection hole 125: body

130: working cylinder

   132: nozzle pin

The present invention relates to a device for supplying the molten resin in the supply device for supplying the molten resin to the mold in the injection molding machine, more specifically, the molten resin is smoothly supplied regardless of the thermal expansion of the manifold according to the supply of the molten resin Of course, the present invention relates to a molten resin supply apparatus for an injection molding machine, which enables to enlarge a molten resin supply apparatus.

In general, the molten resin supply device 100 for supplying the molten resin from the injection molding machine to the mold is supplied with molten resin injected from an injection machine (not shown) on the plurality of plates P as shown in FIG. 6. A manifold 110 having a furnace 112, an injection nozzle 120 having an injection hole 122 for injecting a molten resin supplied from a supply path of the manifold into a mold, and the manifold passing through the manifold; The nozzle pin 132 inserted into the supply passage and the injection hole is configured to open and close the injection hole by the operation cylinder 130 to interrupt the injection of the molten resin.

In the above, the manifold has a heater (not shown) is built in the upper and lower surfaces so that the molten resin supplied through the supply path can be smoothly supplied, and the upper end of the manifold into which the nozzle pin is inserted A guide bush 114 for supporting the nozzle pin so as not to flow back on the supply path and the injection hole is coupled to prevent reverse flow.

In the conventional molten resin supply apparatus configured as described above and provided in the injection molding machine, the manifold made of metal is heated in the horizontal direction by heating the hot melt resin and the heater provided in the manifold through the supply path of the manifold. Thermal expansion occurs to increase, and accordingly, the nozzle pin inserted on the guide bushing coupled to the upper end of the manifold has a problem in that bending occurs due to thermal expansion, thereby preventing shortening of the injection nozzle.

In other words, the nozzle pin is inserted in a state in which there is little spaced space to be supported without fluidity in the guide bushing coupled to the top of the manifold, and the nozzle pin is positioned at the top of the guide bush by thermal expansion of the manifold. Because the warp occurs in the nozzle pin part, the injection hole of the injection nozzle cannot be opened and operated up and down.

Due to the problems described above, the conventional molten resin supply apparatus used in the injection molding machine has a problem in that multiple molten resin supply apparatuses must be installed because the width of the conventional molten resin supplying apparatus is not limited to molding a large injection molding having a long length. I had.

Accordingly, the present invention has been made to solve the conventional problems as described above, the object is to supply the molten resin smoothly regardless of the thermal expansion of the manifold according to the supply of the molten resin in the molten resin supply apparatus of the injection molding machine Of course, it is possible to increase the size of the molten resin supply device and to minimize the fluidity while the nozzle pins move up and down more easily.

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The present invention for achieving the above object, the operation of the nozzle pin is inserted into the injection hole of the injection nozzle and the injection nozzle is formed through the manifold and the injection hole is formed and the injection hole is formed of the molten resin supplied from the injection cylinder In the molten resin supply apparatus for injection molding machine for intermittently supplying the molten resin by the flow of the molten resin, a flow space portion formed to be spaced apart a certain distance between the outer surface of the nozzle pin inserted through the manifold and the inner surface of the manifold ; An auxiliary supply path formed such that the molten resin supplied to the injection nozzle through the supply path is supplied to the injection hole from the upper surface of the body of the injection nozzle through an inner outer side; The upper portion of the injection hole is formed with a support for supporting the nozzle pin is inserted, the support body is formed integrally formed on the upper surface of the body formed with the support, the insertion groove into which the guide support is inserted into the corresponding manifold And a second flow space portion between the guide support and the insertion groove, and the guide support is inserted into the bottom of the guide support and engages the support bush inserted into the nozzle pin from the top of the manifold. A third flow space portion is formed between the support bush and the inner surface of the manifold.

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

1 is a front sectional view of the main portion schematically showing the present invention, Figure 2 is an enlarged cross-sectional view of the main portion of the portion A according to FIG.

As illustrated, a supply path 112 is formed of a molten resin supplied from a general injection machine (not shown), and a manifold 110 having a heater embedded therein and an injection nozzle 120 having an injection hole 122 formed therein. And a well-known injection molding machine for intermittently supplying the nozzle pin 132 inserted into the injection hole 122 of the injection nozzle 120 through the manifold 110 by the operation cylinder 130 to supply molten resin by intermittent action. In the molten resin supply apparatus 100,

According to the present invention, the metal manifold is thermally expanded by the high heat generated by the heater embedded in the lower surface of the hot melt resin and the manifold, and the nozzle pin of the injection nozzle is warped due to thermal expansion, thereby failing to interrupt the nozzle hole. In order to prevent the smooth supply of molten resin,

The outer surface of the nozzle pin 132 inserted through the manifold 110 and the inner surface of the manifold 110 are separated by a predetermined distance so that the portion extending by thermal expansion of the manifold does not come into contact with the nozzle pin. A flow space portion 10 formed to have a flow space;

The auxiliary supply path is formed such that the molten resin supplied to the injection nozzle 120 through the supply path 112 is supplied to the injection hole 122 from the upper surface of the body 125 of the injection nozzle 120 through the inner and outer sides thereof. 20;

The upper portion of the injection hole 122 is the nozzle pin 132 is inserted and supported so that the molten resin supplied through the supply passage and the auxiliary supply passage does not flow back to the manifold side in which the nozzle pin is inserted It shows that the support 30 is formed.

The auxiliary supply passage 20 is the inlet passage 22 formed on the upper surface of the body 125 of the injection nozzle 120 and the injection in the inner outer side of the body 125 perpendicular to the inlet passage 22 It is preferable to form the connection path 24 connected to the ball 122.

As described above, even though the manifold is thermally expanded by the high temperature molten resin supplied through the injection path of the manifold through the injection machine and the heater embedded in the lower surface of the manifold, the manifold penetrates the manifold. The thermal expansion in the spaced apart space portion formed between the outer surface and the inner surface of the nozzle pin to compensate for the increase in the manifold is to prevent the bending of the nozzle pin.

In addition, the supply path of the molten resin supplied to the nozzle hole of the injection nozzle is not directly supplied to the upper side of the nozzle hole, but the inflow path formed in the lower portion from the upper surface of the body of the injection nozzle and the connection path formed orthogonal to the inflow path By supplying the molten resin to the nozzle hole through the auxiliary supply path is formed, it is possible to smoothly supply the molten resin into the injection hole of the injection nozzle from the lower side of the flow space regardless of the thermal expansion of the manifold.

Therefore, the hot melt resin and the heater built in the lower surface of the manifold prevent the bending of the nozzle pin which opens and closes the injection hole of the injection nozzle even when the thermal expansion is generated in the manifold. By doing so, it will have the conditions to improve the efficiency of the work by injection molding.

On the other hand, by allowing the manifold to compensate for the expansion due to thermal expansion as described above, the manifold can be manufactured in a large size, that is, having a condition that can be formed long, it is also easy to produce a long injection molding There will be additional conditions.

3 is a sectional view showing principal parts of another embodiment of the present invention.

In the above configuration as shown, in order to be more smoothly supplied when the molten resin is formed in the injection nozzle is supplied to the injection hole,

The auxiliary supply path 20 is shown to be formed as an inclined ramp 20a to be directly connected to the injection hole 122 in the upper surface of the body 125 of the injection nozzle 120.

In the above, it is preferable that the supply path 112 formed on the manifold 110 in contact with the inclined path 20a is also inclined so that the molten resin supplied through the supply path can be more smoothly supplied.

Accordingly, the molten resin from the supply path of the manifold to the injection hole of the injection nozzle has a condition that can be supplied more quickly through the ramp.

4 is a sectional view showing principal parts of still another embodiment of the present invention.

As shown in the figure, the nozzle pin prevents the molten resin from flowing back to the manifold side at the support formed on the body of the injection nozzle, and moves the nozzle pin smoothly up and down without fluidity. In order to achieve a more stable up and down movement while having greater support,

An extended guide support part 32 is integrally formed on an upper surface of the body 125 on which the support part 30 is formed, and an insertion groove part 34 into which the guide support part 32 is inserted into the corresponding manifold 110. And a second flow space between the guide support part 32 and the insertion groove part 34 so that the portion where the manifold extends due to thermal expansion does not come into contact with the nozzle pin so that warpage does not occur in the nozzle pin. It shows that the portion 36 is formed.

Accordingly, when the nozzle pin is operated to up and down to open and close the nozzle hole of the injection nozzle, the support pin has a longer length so that the nozzle pin has a longer and more stable operation.

5 is a sectional view showing principal parts of still another embodiment of the present invention.

In the above configuration as shown, in order to enable the nozzle pin to move up and down to open and close the nozzle hole to have a higher bearing capacity while moving up and down in a more stable state,

The guide support part 32 is inserted into the bottom of the guide support part 32 and the support bush 40 into which the nozzle pin 132 is inserted from the upper end of the manifold 110 is coupled to the support bush 10. And a third flow space portion 42 between the inner surface of the manifold 110 and a portion extending by thermal expansion of the manifold so that the nozzle pin does not come into contact with the nozzle pin so that warpage does not occur in the nozzle pin. It is shown.

Therefore, the nozzle pin has a greater support force when opening and closing the nozzle hole by the support bushing having the same height as the height of the manifold, thereby minimizing fluidity and also extending the manifold by the thermal expansion. There is no warpage or the like can be smoothly opened and closed.

As described above, when the molten resin is supplied to the mold through the molten resin supply apparatus of the injection molding machine, the present invention compensates for the increase in temperature due to thermal expansion of the manifold by the hot melt resin and the heater embedded in the lower surface of the manifold. It is equipped with a flow space that can be used, and ensures a longer support portion during the up and down movement of the nozzle pin, and to support the nozzle pin at the same height as the manifold, so that the bending of the nozzle pin of the injection nozzle does not occur, melting Not only can the resin be supplied smoothly, but also the length of the manifold can be formed to be large and long, so that the injection molding of the long length can be easily formed, and the holding force of the nozzle pin can be increased, which is more stable. As it is operated up and down in the state, the injection hole can be easily opened and closed, and the nozzle pin has a larger bearing force. May be upper and lower work stably without flowing it has an effect that can be achieved are much more seamless switching.

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Claims (6)

delete delete delete delete delete Injection molding in which the molten resin supplied from the injection machine is intermittently supplied by the operation cylinder with a manifold having a supply passage, an injection nozzle with an injection hole, and a nozzle pin inserted through the manifold into the injection hole of the injection nozzle. In the molten resin supply apparatus for A flow space part 10 formed to be spaced apart from the outer surface of the nozzle pin 132 inserted through the manifold 110 and the inner surface of the manifold by a predetermined distance; The auxiliary supply path is formed such that the molten resin supplied to the injection nozzle 120 through the supply path 112 is supplied to the injection hole 122 from the upper surface of the body 125 of the injection nozzle 120 through an inner outer side thereof. 20; The upper portion of the injection hole 122 is formed with a support portion 30 is inserted into the nozzle pin 132 is supported, the guide guide portion 32 is extended to the upper surface of the body 125, the support portion 30 is formed And an insertion groove portion 34 in which the guide support portion is inserted into the manifold 110 corresponding thereto, and a second flow space portion 36 between the guide support portion 32 and the insertion groove portion 34. To form the upper portion of the guide support portion 32, the guide support portion is inserted into the bottom and coupled to the support bush 40 is inserted into the nozzle pin 132 from the top of the manifold 110 and the support bush ( 40) and a molten resin supply apparatus for an injection molding machine, characterized in that to form a third flow space portion 42 between the inner surface of the manifold (110).

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