KR102117067B1 - Air supply nozzle structure for injection molding machine - Google Patents

Abstract

The present invention prevents clogging of the air supply path of the air supply nozzle by minimizing the penetration of the molten resin into the air supply nozzle, and improves the structure of the injection molding machine to improve the assembly and disassembly of the air supply nozzle. It relates to an air supply nozzle structure.
The present invention is composed of a fixed mold and a movable mold in which the process of being combined with and separated from the fixed mold is repeatedly performed, and when the fixed mold and the movable mold are combined, a mold of an injection molding machine having a cavity corresponding to a product to be produced is formed. and; A plurality of air supply units provided to correspond to the first, second and third nozzle bodies on the outside of the fixed mold; Air supply pipes for first and second and third nozzle bodies formed inside the fixed mold so as to supply air supplied from each of the plurality of air supply units to the cavity side, respectively; And a head portion coupled to be fitted into the front end portion of the air supply pipe communicating with the cavity to prevent the molten resin in the cavity from penetrating into the air supply pipe, and air is formed between the outer peripheral surface of the head portion and the inner peripheral surface of the air supply pipe. The nozzle body is provided with a gap to be supplied to the side.

Description

Air supply nozzle structure of injection molding machine {AIR SUPPLY NOZZLE STRUCTURE FOR INJECTION MOLDING MACHINE}

The present invention relates to an air supply nozzle structure of an injection molding machine, and in particular, to prevent the penetration of molten resin into the air supply pipe in the injection molding machine, to smoothly supply air into the cavity, and to provide air in the cavity through a plurality of air supply units. The present invention relates to an air supply nozzle structure of an injection molding machine whose structure is improved so that uniform pressure is distributed in the cavity to minimize product deformation and molding defects even at a distance from the gate.

Generally, a metal mold is a metallic mold for molding a highly finished product with a complex shape by using plasticity and fluidity of a material. It can be classified into a press mold producing a product and a die casting mold produced similar to plastic by dissolving metal.

Among these various types of molds, injection molds produce a product that is a predetermined molded product identical to the inside shape of the mold by injecting and cooling the cavity formed between each mold, that is, a high temperature liquid resin material inside the molding space. Is done.

The injection mold is largely divided into a fixed part mold and a movable part mold. Specifically, a cavity part for injecting and filling a molding material into a mold cavity to obtain a molded product, a flow mechanism for guiding molten material from the nozzle of the molding machine to the cavity, It is divided into an ejector mechanism for removing molded products from a mold, a temperature control unit for adjusting the temperature of the mold, an attachment portion for attaching the mold to the molding machine, and a mold base as a whole frame for maintaining it.

In addition, in the injection molding method using the injection mold, a thermoplastic or thermosetting plastic molding material is heated and melted in an injection molding machine, and then, through a sprue, the raw material is injected into the molding space of the injection mold, and this is injected into the injection mold. It is a method of separating each mold and taking out the molded product after solidification or curing is completed.

The manufacturing method by the injection mold as described above has the advantages of high dimensional precision of the production product, simple production of compatible assemblies, production of the product is possible without special skills or skill, and the production time of the product is shortened. have.

However, when an undercut (a concave portion in which it is difficult to discharge the molded article only by movement of the closing or opening direction of the injection mold) is formed inside the molded article, the molded part in the cavity cannot be taken out only by moving the mold of the movable part Will occur.

In addition, in the prior art, a forced extraction method has been used in which the core mold is forcibly taken out of the molding body to take out the molded article on which the under-cut is formed, and this method has another problem such as the shape of the molding is deformed or scratched. Caused.

In order to solve the above problems, the prior art composed of an injection molding mold for forming a product having an undercut inside has an injection with an undercut when at least one of the two moves close to each other and is in close contact with each other with the upper and lower discs in close contact with each other. An injection space corresponding to the shape of the molded product is formed, and includes an upper core supported on the upper disc and a lower core supported on the lower disc, wherein the lower core is fixed to the lower disc and fixed block A movable block that is movable between a position when the upper core and the lower core are in close contact with each other and a position when the injection molded product molded in the injection space is taken out from the lower core, and the fixed block corresponding to the shape of the undercut It is made of a block for forming an undercut that is elastically pressed so as to be in close contact with it.

That is, in the prior art, an inclined surface inclined with respect to the direction of the elastic pressing force applied to the undercut forming block is formed on one side of the fixed block, and when the moving block moves upward, the undercut forming block inclines the fixed block. It is configured to move in an inclined direction along such that the block for forming the undercut is spaced from the undercut of the injection molded product.

However, in the prior art, it is necessary to install a block and device for forming an undercut, which is a separate slide mold, to form an undercut on a molded product, and it is not easy to manufacture such an undercut forming device, and the cost for manufacturing the slide mold is high. Lifting, the weight of the mold itself became heavy, there was a problem that a lot of power to drive the mold.

In addition, in the prior art, since the moving block moves upward to take out the molding formed with the undercut, the undercut forming block has to undergo a series of processes to move in an inclined direction along the inclined surface of the fixed block, so that the molding is taken out from the injection mold. It takes a lot of time to do this, and even if a slight error occurs when moving the molds, there is a problem that each mold is collided and damaged.

In addition, after the liquid raw material is injected into the cavity, it is in contact with the entire molded surface, so the adhesion to the molded surface is large, and when the molten water support material hardens and falls off the molded surface, or the molding of the product is completed. When the metal product is separated from the mold, the entire product does not completely run out, and a part of the product is torn off from the rest while being pressed against the molding surface.

In addition, since a contraction occurs due to a density difference in a region (300 mm or more) where the molten resin reaches a distance from the existing gate, when two or more gates are provided to prevent this, a weld line is inevitably generated. In order to control the production of the line, a steam mold that increases the fluidity of the molten resin is adopted, but in this case, the steam mold is not only expensive, but also because of the use of high-temperature steam, the cooling performance deteriorates and it takes longer to manufacture. In addition, there was a risk of safety accidents due to steam leakage.

An injection molding machine capable of overcoming the disadvantages while maintaining the advantages of the existing steam mold was required, and in order to improve this, a technique has been proposed in which air is injected into the mold to pressurize the pressure in the mold, and related prior art is Korea As disclosed in Patent Publication No. 10-1578294 "Pressurized Injection Mold" (Registration Date: 2015.12.10), in an injection mold, the injection mold has a fixed mold whose position is fixedly coupled to the injection machine, and the It is composed of a movable mold in which the process of being combined with and separated from the fixed mold is repeatedly performed. When the fixed mold and the movable mold are combined, a cavity having a shape corresponding to a product to be produced is formed, and the entire cavity is surrounded around the cavity. It is characterized in that the packing or O-ring is combined in the form, and the cavity is in communication with an air injection passage formed to inject air or gas.

As another prior art related to the injection of air into an existing mold, as disclosed in Korean Registered Utility Model Publication No. 20-0455773 "Air supply device for injection molding machine" (Registration date: 2011.09.19), it is supplied through an injection material supply path. A nozzle of an injection molding machine in which the supply of resin is controlled by a valve pin that moves up and down by air before the molten resin reaches the end of the nozzle; A first connection block mounted close to one side of the nozzle and exposed at one end of two first air supply paths to the bottom surface and the other side of the first air supply path to supply air to the valve pin; Is coupled to the bottom and side surfaces of the first connection block, each having two second air supply paths in communication with the first air supply path, the other end of the second air supply path is provided with an air conditioning control valve It relates to an air supply device of an injection molding machine characterized in that it is configured to supply air by a second connection block.

As another prior art related to the air supply of the existing injection molding machine, as disclosed in Korean Patent Registration No. 10-1891960 "Injection molding air supply device" (Registration date: 2018.08.21), to remove air impurities An air supply unit consisting of an air filter and a filter regulator for adjusting the supply pressure of air; An air pressurizing unit configured to boost the air supplied through the air supply unit to 100 bar to 120 bar, and to include a boost control valve for controlling a boost range of the pressure of the air; An air storage unit that stores air at a predetermined pressure from the air pressurization unit and discharges condensate contained in the stored air; A supply amount adjusting unit supplying high pressure air stored in the air storage unit to a mold side; A supply valve that controls the flow of resin by supplying high-pressure air to each part of the mold by supplying high-pressure air supplied by the supply amount adjusting unit to a necessary part of the mold, respectively; And a supply control unit controlling the driving of the air supply device, and controlling the supply of air at high pressure by setting the pressure and time of the air supplied in accordance with the cycle signal of the injection machine during mass production of the injection material. When the air is supplied through the air filter, the supply control unit controls the filter regulator and the boost control valve to boost the air pressure to a preset pressure of 100bar to 120bar, and when the boost is completed, the air It is transferred to the air storage unit side, and the supply amount adjusting unit supplies high-pressure air pressurized toward the supply valve at a pressure of 100 bar, and supply is made according to the supply value set by the supply control unit as a necessary part of the mold in the supply valve. , The supply control unit controls to select the supply pressure and time of air to enable control by mode, and the control for each mode sets the supply pressure and time of air, and automatically adjusts the set supply value (supply pressure and time). Automatic mode for supplying high pressure air, manual mode for ejecting high pressure air by manually operating a valve when replacing molds or removing gas remaining in the flow path, and after setting the supply value, the injection machine is previewed 1 cycle test mode to test so that the supply value setting can be confirmed and changed by operating only one cycle in accordance with the released injection machine signal, and the pressure being pressed while the mold is pressed, and the pressure change is notified. It is characterized by selecting one of the leakage test modes.

By the way, the air supply device of the existing injection molding machine has a technical idea to variably control the supply of air, but as the molten resin flows into the air supply nozzle, the air supply nozzle is closed as it hardens, so that the air injection amount is insufficient or severely air injection. There was a fear that this would become impossible.

Korean Registered Patent Publication No. 10-1578294 "Pressurized Injection Mold" (Registration Date: 2015.12.10) Korean Registered Utility Model Publication No. 20-0455773 "Air supply device for injection molding machine" (Registration date: 2011.09.19) Korea Patent Registration No. 10-1891960 "Injection molding air supply device" (Registration date: 2018.08.21)

The present invention was created to solve the above problems in consideration of the above-mentioned problems, and its purpose is to improve the structure of the air supply nozzle and supply air into the cavity through the air supply pipe while minimizing the penetration of molten resin to minimize the penetration of the air supply nozzle. An object of the present invention is to provide an air supply nozzle structure of an injection molding machine whose structure is improved so as to prevent clogging of the air supply path.

The present invention for achieving the above object is composed of a fixed mold, a movable mold in which the process of being combined with and separated from the fixed mold is repeatedly performed, and a shape corresponding to a product to be produced when the fixed mold and the movable mold are combined. An injection mold in which the cavity of the is formed; A plurality of air supply units provided to correspond to the first, second and third nozzle bodies on the outside of the fixed mold; Air supply pipes for first and second and third nozzle bodies formed inside the fixed mold so as to supply air supplied from each of the plurality of air supply units to the cavity side, respectively; And a head portion coupled to be fitted into the front end portion of the air supply pipe communicating with the cavity to prevent the molten resin in the cavity from penetrating into the air supply pipe, and air is formed between the outer peripheral surface of the head portion and the inner peripheral surface of the air supply pipe. The nozzle body is provided with a gap to be supplied to the side; including, the nozzle body is a first nozzle for supplying air to the cavity of the flat part having the highest height of the cavity where the upper surface of the head portion is formed in a flat shape and the molded product is molded. The body and the second nozzle body for supplying air to the cavity of the rib portion where the upper surface of the head portion is formed as an oblique inclined surface and the undercut molding of the molded product is formed, and the upper surface of the head portion is formed in a flat shape and the height of the molded product Is composed of a third nozzle body for supplying air to the cavity of the lowest groove portion,
Each of the first and second nozzle bodies has a hollow of the first and second nozzle bodies in communication with the second supply pipes of the air supply pipes for the first and second nozzle bodies, and a lower side of the head portion through a communication hole in communication with the hollow. Air is supplied to the circumferential jaw side, and the third nozzle body is provided with a gap between the second chamfered portion and the air supply hole formed on the outer circumferential surface of the third nozzle body in communication with the third supply pipe of the third nozzle body air supply pipe. It is characterized in that air is supplied to the small-diameter portion side through the head portion.

Each of the first and second nozzle body air supply pipes connected to the first and second nozzle bodies is connected to a first supply pipe connected in a horizontal direction from the air supply unit, and in communication in a direction perpendicular to the first supply pipe. It consists of a second supply pipe connected to communicate with the hollow of the 1,2-nozzle body, and an air supply hole through which the first and second nozzle bodies are fitted and air supplied through the hollow is supplied to the cavity side.

The first and second nozzle bodies are coupled to be press-fitted into the air supply hole in the fixed mold, and have a hollow formed therein to communicate with the second supply pipe, and a perimeter formed to have an outer diameter smaller than the outer diameter of the head portion below the head portion. The chin portion and the circumferential chin portion are provided with a plurality of first chamfered portions formed to have a gap with the air supply hole by chamfering on a portion of the outer circumferential surface of the head portion and communicating with the end portions of the hollow and opening to both sides.

The length of the first nozzle body is longer than the second nozzle body, and the length of the second nozzle body is longer than the length of the third nozzle body.

The air supply pipe for the third nozzle body connected to the third nozzle body includes a first supply pipe connected in a horizontal direction from the air supply unit, a second supply pipe connected in communication in a direction orthogonal to the first supply pipe, and the first 2 It is composed of a third supply pipe connected from the end of the supply pipe and branched to both left and right sides, and an air supply hole for supplying air supplied from the third supply pipe to the cavity side, wherein the third nozzle body is fitted into the air supply hole An upper surface of a flat shape is formed on the upper portion, and a head portion in which a first chamfering portion is formed by chamfering on a part of the outer circumferential surface, a small diameter portion formed at an outer diameter smaller than the outer diameter of the head portion at a lower side of the head portion, and extended at a lower side of the small diameter portion It is composed of a large diameter portion with a second chamfer formed by chamfering on a part of the outer circumferential surface.

The gap of the nozzle body is that the gap is formed by any one selected from a plurality of first chamfers formed by chamfering or a plurality of grooves formed by groove processing on the outer circumferential surface of the head of the nozzle body.

The present invention allows the air to be supplied into the cavity to minimize forming defects such as sink marks and to allow uniform pressure to act even at a long distance from the gate after the molten resin is filled in the cavity, and also a nozzle in the air supply hole Since the body is coupled to be accommodated, the upper surface of the head of the nozzle body has a useful advantage to prevent the molten resin from penetrating into the air supply hole, which is a path through which air is injected into the cavity.

In addition, according to the present invention, since the first chamfering portion in a flat shape is formed by chamfering around the outer circumferential surface of the head portion, air can be supplied into the cavity through the gap between the first chamfering portion and the air supply hole, but the head portion excluding the gap Since the upper surface occupies the inside of the air supply hole, it has an advantage that the penetration of the molten resin into the air supply hole can be easily suppressed.

1 is a plan view showing an embodiment configuration of the air supply nozzle structure of the injection molding machine according to the present invention.
Figure 2 is a side view of Figure 1;
Figure 3 is a perspective view showing the first nozzle body of the present invention.
4 is a front view of FIG. 3;
Figure 5 is a perspective view showing a second nozzle body of the present invention.
Figure 6 is a front view of Figure 5;
7 is a plan view showing a state in which the head portion of the nozzle body is accommodated in the air supply hole of the present invention.
8 is a perspective view showing a third nozzle body of the present invention.
Figure 9 is a state diagram showing the process of supplying air through the first and second nozzle bodies of the present invention in a cavity sequentially.
Figure 10 is a state of use sequentially showing the process of supplying air through the third nozzle body of the present invention in the cavity.
11 is a perspective view showing a fourth nozzle body in another embodiment of the air supply nozzle structure of the injection molding machine according to the present invention.
Figure 12 is a plan view showing the coupling state of the head and the air supply hole of the fourth nozzle body of the present invention.

The present invention allows the supply of air to the cavity smoothly while preventing the penetration of molten resin into the air supply pipe in the injection molding machine, and air is supplied into the cavity through a plurality of air supplying portions so that uniform pressure is distributed in the cavity. Product deformation can be minimized even at a distance from the gate.

Hereinafter, the air supply nozzle structure of the injection molding machine according to the present invention will be described in more detail through detailed description of embodiments with reference to the drawings.

In describing the present invention, when it is determined that detailed descriptions of related known technologies or configurations may unnecessarily obscure the subject matter of the present invention, detailed descriptions thereof will be omitted. In addition, terms to be described later are terms defined in consideration of functions in the present invention and may vary according to a user's intention or custom. Therefore, the definition should be made based on the contents throughout this specification. In addition, "including" a component means that other components may be further included, not excluded, unless otherwise stated.

1 to 10 for an embodiment of the air supply nozzle structure of the injection molding machine according to the present invention, a fixed mold 12 and a movable mold in which the fixed mold 12 is repeatedly coupled and separated It is composed of (14), the fixed mold 12 and the movable mold 14 when the combination of the product 50 to be produced when the cavity 30 of the shape corresponding to the product 30 is formed and the injection mold 10; A plurality of air supply units 100 provided to correspond to the first, second, and third nozzle bodies 300A, 300B, and 300C on the outside of the fixed mold 12; First, second, and third nozzle bodies 300A, 300B, 300C formed in the fixed mold 12 so as to supply air supplied from each of the plurality of air supply units 100 to the cavity 30 side, respectively. 200); And a head portion 310 coupled to be fitted into the front end portion of the air supply pipe 200 communicating with the cavity 30 to prevent the molten resin in the cavity 30 from penetrating into the air supply pipe 200. , A gap (t) is provided between the outer circumferential surface of the head portion 310 and the inner circumferential surface of the air supply pipe 200 so that air is supplied to the cavity 30 side.

Here, the injection molding machine is an example of an undercut injection molding machine.

The injection mold 10 is provided with an inclined pin and an inclined core.

The air supply unit 100 may be provided with a supply nipple so that external air is supplied into the air supply pipe 200 through a supply pipe. In addition, as shown in FIGS. 1 and 2, the air supply unit 100 is provided in plurality to correspond to the first, second, and third nozzle bodies 300A, 300B, and 300C.

1 and 2, each of the air supply pipes 200 for the first and second nozzle bodies 300A and 300B among the nozzle bodies 300 is connected first to the horizontal direction from the air supply unit 100. The supply pipe 210 and the first supply pipe 210 are connected in communication in an orthogonal direction and are connected to communicate with the hollow 305 of the first and second nozzle bodies 300A and 300B among the nozzle bodies 300. 2 Supply pipe 220, the first and second nozzle body (300A, 300B) of the nozzle body 300 is fitted and the head portion (air) supplied through the hollow 305 is supplied to the cavity (30) side ( It is made of an air supply hole 250 that is coupled to have the first chamfered portion 312 of 310) and a gap (t).

The gap t formed between the first chamfered portion 312 of the head portion 310 and the air supply hole 250 is the head of the first and second nozzle bodies 300A and 300B of the nozzle body 300 As a gap between the outer peripheral surface of the portion 310 and the inner peripheral surface of the air supply hole 250, the first chamfered portion 312 formed in a flat shape on the outer peripheral surface of the head portion 310 described below and the air supply hole having a circular cross-section structure It occurs due to the structural characteristics of (250).

To this end, each of the first and second nozzle bodies 300A and 300B of the nozzle body 300 is press-fitted into the air supply hole 250 in the fixed mold 12, as shown in FIGS. 3 and 5. The hollow 305 of the first and second nozzle bodies 300A and 300B formed to be connected to the second supply pipe 220 of the air supply pipe 200 for the first and second nozzle bodies 300A and 300B. And, the circumferential jaw portion 320 is formed to have an outer diameter smaller than the outer diameter of the head portion 310 on the lower side of the head portion 310, the circumferential jaw portion 320 communicates with the end portion of the hollow 305, left and right A communication hole 307 formed to be opened on both sides and a part formed on the outer circumferential surface of the head part 310 by chamfering to form a gap t with the air supply hole 250 It consists of one chamfer 312.

The first chamfering portion 312 is formed in a plurality of plane shapes by chamfering at regular intervals on the outer circumferential surface of the head portion 310.

The nozzle body 300 has a first nozzle body 300A for supplying air to the highest height of the cavity 30 in which the upper surface of the head portion 310 is formed in a flat shape and the molded product 50 is molded. ), as shown in Figures 5 and 6, the upper surface of the head portion 310 is formed as an oblique inclined surface and a second for supplying air to the rib portion where shrinkage frequently occurs in the molded product 50 It is divided into a nozzle body (300B).

To this end, the length of the first nozzle body 300A is formed longer than the length of the second nozzle body 300B.

In addition, the top surface of the head portion 310 of the nozzle body 300 may have a circular or elliptical cross-sectional structure, and may have a cross-sectional circular or elliptical cross-sectional structure of the air supply hole 250 corresponding thereto.

The first and second nozzle bodies 300A and 300B have a structure in which a hollow 305 is formed inside and a communication hole 307 communicating with the hollow 305 is formed in the circumferential jaw portion 320.

The path through which the air is supplied to the cavity 30 through the first and second nozzle bodies 300A and 300B is the air supply pipe 200 from each of the air supply parts 100 for the first and second nozzle bodies 300A and 300B. ) Flows into the second supply pipe 220 through the first supply pipe 210, and then the circumferential jaw portion 320 through the hollow 305 of the first and second nozzle bodies 300A and 300B in the second supply pipe 220 ) Is supplied to the left and right branches into the communication hole 307, and then through the gap (t) between the first chamfering portion 312 of the head portion 310 and the inner circumferential surface of the air supply hole 250 ( 30) has a structure supplied into.

As shown in FIG. 7, the gap t is formed as a gap between the first chamfer 312 and the inner circumferential surface of the air supply hole 250, and the gap t is a gap of 0.03 mm to 0.07 mm It is preferably formed to have, and if less than 0.03mm, the inflow space of the air is insufficient, and when it exceeds 0.07mm, there is a fear that molten resin may penetrate into the air supply hole 250. The most preferred gap t is 0.05 mm.

In addition, the air supply pipe 200 for the third nozzle body 300C, which is connected to the third nozzle body 300C among the nozzle bodies 300, is configured to inject air into the groove portion of the molded product 50 ( 100) from the first supply pipe 210 connected in the horizontal direction, the second supply pipe 220 connected in communication in a direction perpendicular to the first supply pipe 210, and from the end of the second supply pipe 220 It is composed of a third supply pipe 230 that is connected and branched to both left and right sides, and an air supply hole 250 that supplies air supplied from the third supply pipe 230 to the cavity 30 side, and the nozzle corresponding thereto The third nozzle body 300C of the body 300 has a length relatively shorter than that of the first and second nozzle bodies 300A and 300B, and is inserted into the air supply hole 250 and has a flat shape on the top. A head portion 310 having an upper surface formed and a first chamfering portion 312 formed by chamfering on a part of the outer circumferential surface, and a cow formed with an outer diameter smaller than the outer diameter of the head portion 310 below the head portion 310. The third portion consisting of a large portion 340 formed with a second chamfer 342 to communicate with the third supply pipe 230 through a chamfering process on a portion of the outer circumferential surface extending to the lower portion of the neck portion 330 and the small diameter portion 330 The nozzle body 300C may be employed.

8, the second nozzle body 300C has a second surface on the lower outer circumferential surface instead of a hollow 305 formed therein, unlike the first and second nozzle bodies 300A and 300B described above. The mounting portion 342 is formed to have a structure in which a gap t ₁ and an inner circumferential surface of the air supply hole 250 are formed to allow air to flow in.

In addition, the third supply pipe 230 is connected to the air supply hole 250 corresponding to a portion where the second chamfered portion 342 of the third nozzle body 300C is disposed to be spaced apart from the left and right. Air is introduced (supplied) to the small diameter portion 330 under the head portion 310 through the gap t between the second chamfered portion 342 of the large diameter portion 340 and the air supply hole 250, and then the head It has a structure that is supplied into the cavity 30 through the first chamfering portion 312 of the portion 310.

That is, the nozzle body 300 may be used by dividing the first, second, and third nozzle bodies 300A, 300B, and 300C according to the shape of the molded product 50 or omitting some of them.

One embodiment of the present invention having such a configuration, the movable mold 14 is moved to the fixed mold 12 side is formed as a cavity 30 is formed, the molten resin through the gate and runner cavity 30 In the course of being supplied and cured, air is supplied into the cavity 30 to compensate for uniform pressure in the cavity 30 at a distance from the gate.

As shown in FIG. 9, the supply path of air supplied into the cavity 30 is first, in the case of the first and second nozzle bodies 300A and 300B among the nozzle bodies 300, external air is injected as described above. The first and second nozzle bodies 300A through the first supply pipe 210 and the second supply pipe 220 of the air supply pipe 200 for the first and second nozzle bodies 300A and 300B from each of the air supply units 100 to be , 300B) flows into the hollow 305 inside, flows upwards of the hollow 305, and the inside of the air supply hole 250 through the communication holes 307 opened on both left and right sides of the circumferential jaw portion 320 Is introduced into the cavity 30 through the clearance gap t between the first chamfering portion 312 of the head portion 310 and the air supply hole 250 in the inside of the air supply hole 250.

On the other hand, the supply path of the air supplied into the cavity 30 through the third nozzle body 300C of the nozzle body 300 is as shown in FIG. 10, from the air supply unit 100 through which external air is injected. Air supply provided on both left and right sides by a third supply pipe 230 branched left and right through the first supply pipe 210 and the second supply pipe 220 of the air supply pipe 200 for the third nozzle body 300C The ball 250 flows into the inside, and flows into the small diameter portion 330 through the gap t between the inner circumferential surface of the air supply hole 250 and the second chamfered portion 342 of the third nozzle body 300C, Air introduced into the small-diameter portion 330 flows into the cavity 30 through the gap t between the first chamfered portion 312 of the head portion 310 and the air supply hole 250.

At this time, the portion of the cavity 30 in which the first nozzle body 300A is disposed is provided in a portion corresponding to the plane of the molded product 50 at the highest height, and the cavity in which the second nozzle body 300B is disposed (30) The molded product (50) is provided at a portion close to the rib portion where the undercut molding is performed, and the cavity (30) portion where the third nozzle body (300C) is disposed is the lowest height of the molded product (50). It is provided in the groove part.

Accordingly, the length of the first nozzle body 300A is longer than that of the second nozzle body 300B, and the length of the second nozzle body 300B is longer than that of the third nozzle body 300C. .

11 and 12 are another embodiment of the air supply nozzle structure of the injection molding machine of the present invention, among the components of the above-described embodiment, the injection mold 10 and the air supply unit 100 provided outside the fixed mold 12 And, the air supply pipe 200 formed inside the fixed mold 12 so as to supply the air supplied from the air supply unit 100 to the cavity 30 side, and the front end portion of the air supply pipe 200 communicating with the cavity 30 It includes a nozzle body 300 coupled to fit within, the nozzle body 300 is coupled to be pressed into the air supply hole 250 in the fixed mold 12, the second supply pipe 220 therein The hollow 305 formed to be in communication, the circumferential jaw portion 320 formed to have an outer diameter smaller than the outer diameter of the head portion 310 below the head portion 310, and the hollow 305 to the circumferential jaw portion 320 ) And a plurality of communication holes 307 formed to open at both sides of the left and right, and a plurality of gaps formed with the air supply holes 250 through grooves on a part of the outer circumferential surface of the head part 310. It is a fourth nozzle body 300D having a recess groove 315.

That is, in another embodiment of the present invention, instead of the first chamfering portion 312 of the head portion 310 formed by the chamfering described above, the recess 315 has an inner circumferential surface and a gap t of the air supply hole 250 The air is supplied to the inside of the cavity 30 through the recess 315.

In this case, the air supply path is the hollow of the fourth nozzle body 300D through the first supply pipe 210 and the second supply pipe 220 of the air supply pipe 200 from the air supply unit 100 through which external air is injected. (305) flows into the inside, flows to the upper side of the hollow 305, flows into the inside of the air supply hole 250 through the communication holes 307 opened on both the left and right sides of the circumferential jaw portion 320, air The inside of the supply hole 250 is supplied into the cavity 30 through the clearance gap t between the groove 315 of the head portion 310 and the air supply hole 250.

Therefore, the present invention allows the air to be supplied into the cavity 30 so as to allow uniform pressure to act even at a distance from the gate after the molten resin is filled in the cavity 30 and to minimize molding defects such as sink marks. In addition, since the nozzle body 300 is coupled to be accommodated in the air supply hole 250, the upper surface of the head portion 310 of the nozzle body 300 is an air supply hole 250 that is a path through which air is injected into the cavity 30 ) It has a useful advantage to prevent the penetration of molten resin into the interior.

In addition, in the present invention, since the first chamfering portion 312 in a flat shape is formed by chamfering around the outer circumferential surface of the head portion 310, the gap between the first chamfering portion 312 and the air supply hole 250 ( While the air can be supplied into the cavity 30 through t), the upper surface of the head portion 310 excluding the gap t occupies the inside of the air supply hole 250 so that the air supply hole 250 of the molten resin It has the advantage of easily suppressing the penetration.

As described above, although specific embodiments have been described in the detailed description of the present invention, various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the above-described embodiment, but should be defined by the claims and equivalents as well as the claims below.

That is, the present invention as described above is not limited to the specific preferred embodiments described above, and who has ordinary knowledge in the technical field to which the present invention belongs without departing from the gist of the present invention claimed in the claims. Of course, various modifications are possible, and such changes are within the scope of the claims.

10: injection mold 12: fixed mold
14: movable mold 30: cavity
50: molded product 100: air supply
200: air supply pipe 210: first supply pipe
220: second supply pipe 230: third supply pipe
250: air supply hole 300: nozzle body
300A,300B,300C,300D: No. 1, 2, 3, 4 nozzle body
305: hollow 307: communication hole
310: head portion 312: first chamfer
315: recess groove 320: circumferential jaw
330: small diameter 340: large diameter
342: second chamfer t: gap

Claims (6)

It consists of a fixed mold 12 and a movable mold 14 in which the process of being combined with and separated from the fixed mold 12 is repeatedly performed, and is intended to be produced when the fixed mold 12 and the movable mold 14 are combined. An injection mold 10 in which a cavity 30 having a shape corresponding to the product 50 is formed;
A plurality of air supply parts 100 provided to correspond to the first, second, and third nozzle bodies 300A, 300B, and 300C on the outside of the fixed mold 12;
Each of the first, second, and third nozzle bodies 300A, 300B, and 300C formed inside the fixed mold 12 so as to supply air supplied from each of the plurality of air supply units 100 to the cavity 30 respectively. Air supply pipe 200; And
It is coupled to fit within the front end portion of the air supply pipe 200 communicating with the cavity 30, and has a head portion 310 for preventing the molten resin in the cavity 30 from penetrating into the air supply pipe 200, The nozzle body 300 is provided with a gap t so that air is supplied to the cavity 30 between the outer circumferential surface of the head part 310 and the inner circumferential surface of the air supply pipe 200.
The nozzle body 300 is for supplying air to the cavity 30 of the flat portion having the highest height of the cavity 30 in which the upper surface of the head portion 310 is formed in a flat shape and the molded product 50 is molded. The first nozzle body 300A and the second nozzle for supplying air to the cavity 30 of the rib portion where the upper surface of the head portion 310 is formed as an oblique inclined surface and undercut molding of the molded product 50 is performed. Body (300B), the upper surface of the head portion (310) is formed in a flat shape, and the third nozzle body (300C) for supplying air to the cavity (30) of the grooved part having the lowest height of the molded product (50) Composed,
Each of the first and second nozzle bodies 300A and 300B is a first and second nozzle body communicating with each of the second supply pipes 220 of the air supply pipes 200 for the first and second nozzle bodies 300A and 300B ( The air is supplied to the circumferential jaw portion 320 below the head portion 310 through the hollow 305 of the 300A, 300B and the communicating hole 307 communicating with the hollow 305, and the third nozzle body ( 300C) is a second chamfer 342 formed on the outer circumferential surface of the large diameter portion 340 of the third nozzle body 300C in communication with the third supply pipe 230 of the air supply pipe 200 for the third nozzle body 300C. Air supply nozzle structure of the injection molding machine, characterized in that the air is supplied to the small diameter portion 330 side of the head portion 310 through the gap (t1) between the air supply hole 250. The method according to claim 1,
Each of the air supply pipes 200 for the first and second nozzle bodies 300A and 300B connected to the first and second nozzle bodies 300A and 300B is connected to the first supply pipe horizontally from the air supply unit 100 (210),
A second supply pipe 220 connected in communication with the first supply pipe 210 in a direction orthogonal to the hollow 305 of the first and second nozzle bodies 300A and 300B,
Wherein the first and second nozzle body (300A, 300B) is fitted, the air supplied through the hollow 305, the air of the injection molding machine, characterized in that consisting of an air supply hole 250 supplied to the cavity 30 side Supply nozzle structure. The method according to claim 2,
The first and second nozzle bodies 300A and 300B are coupled to be press-fitted into the air supply hole 250 in the fixed mold 12, and a hollow 305 formed to communicate with the second supply pipe 220 therein , A circumferential jaw portion 320 formed to have an outer diameter smaller than the outer diameter of the head portion 310 on the lower side of the head portion 310, and the left and right sides of the circumferential portion 320 communicating with the ends of the hollow 305. A plurality of first chamfering portions 312 formed to have a gap t with the air supply hole 250 through a chamfering process on a portion of the outer circumferential surface of the head portion 310 and the communication hole 307 formed to be opened to Air supply nozzle structure of the injection molding machine, characterized in that provided. The method according to claim 1,
The length of the first nozzle body (300A) is formed longer than the second nozzle body (300B), the length of the second nozzle body (300B) is formed longer than the length of the third nozzle body (300C) Air supply nozzle structure of injection molding machine. The method according to claim 1,
The air supply pipe 200 for the third nozzle body 300C connected to the third nozzle body 300C includes a first supply pipe 210 connected in a horizontal direction from the air supply unit 100, and the first supply pipe ( 210) and a second supply pipe 220 connected in communication in an orthogonal direction, a third supply pipe 230 connected from the ends of the second supply pipe 220 and branching to both left and right sides, and the third supply pipe 230 ) Is made of an air supply hole 250 for supplying the air supplied from the side to the cavity 30,
The third nozzle body 300C is fitted into the air supply hole 250, a top surface of a flat shape is formed on the upper portion, and a head portion 310 having a plurality of first chamfering portions 312 formed by chamfering on a part of the outer circumferential surface ), a small diameter portion 330 formed on the lower side of the head portion 310 with an outer diameter smaller than the outer diameter of the head portion 310, and extended on the lower side of the small diameter portion 330 and chamfered on a portion of the outer circumferential surface. Air supply nozzle structure of the injection molding machine, characterized in that consisting of a large diameter portion 340 is formed with a two-chamfered portion (342). The method according to claim 1,
The gap t of the nozzle body 300 is a plurality of first chamfers 312 formed by chamfering on the outer circumferential surface of the head portion 310 of the nozzle body 300 or a plurality of grooves 315 formed by groove processing. ) A gap (t) is formed by any one selected from the air supply nozzle structure of the injection molding machine.

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