KR20120122862A - Hotrunner system - Google Patents

Abstract

PURPOSE: A hot runner valve unit for injection molding is provided to restrict the supply of resin by using a lift pin. CONSTITUTION: A hot runner valve unit for injection molding comprises a nozzle(20) and a lift pin(30). The lift pin is installed in the nozzle. The lift pin is lifted by an ascending and descending drive element the lift pin comprises a body and a movement control tip. Resin flows in the body. The movement control tip is formed in the lower portion of the body integrally. When the lift pin is descended, the end portion of the movement control tip is contacted with the cavity of a mold.

Description

Hot runner valve device for injection molding machine {Hotrunner system}

The present invention relates to a hot runner valve device for an injection molding machine for injecting molten resin into a cavity of a mold, and more particularly, by intermittently supplying a resin by using a phenomenon in which the resin solidifies and melts due to a temperature difference. The present invention relates to a hot runner valve device for an injection molding machine capable of satisfactorily forming a molding condition for a small precision part or a resin having poor fluidity, increasing mass productivity, and reducing occurrence of defective products.

In general, an injection molding machine for molding a plastic product injects a water support material into a manifold from a mold cylinder in which resin is melted, and the injected resin is distributed evenly along a resin channel branched in the manifold to be coupled to the bottom of the manifold. It is a device that is supplied to each of the at least one nozzle and injected into the molding space, that is, the cavity formed by the upper and lower cores that are product forming molds.

The injection molding machine is configured to open and close the outlet by lifting and lowering of the valve pin, and in the case of molding several pieces at once according to the quantity of molded products, a manifold type that receives resin through a manifold is used, and is produced separately. In case of a single type, a single type is used.

1 is a schematic cross-sectional view of a hot runner system for an injection molding machine for lifting and lowering a valve pin using a high-pressure air as a working pressure according to the prior art.

As shown in the related art, the conventional multi-cavity injection molding machine valve device is composed of a driving unit 100 and the valve device 200 and uses high pressure air as a driving source for the lifting operation of the valve pin 210. That is, the driving unit 100 is formed with a plurality of air channels (110, 120) which is a pipe for supplying and discharging air of high pressure from the outside, and selectively through the plurality of air channels (110, 120) The piston 140 in the cylinder 130 moves up and down by the high pressure air flowing in. At this time, the lower end of the piston 130 has a structure in which the valve pin 210 is connected and interlocked.

In addition, the valve pin 210 is configured to selectively block or open the outlet forming the tip of the nozzle 220 by being lifted and linked with the piston 130.

On the other hand, the valve device 200 includes a nozzle 220 to which the heater is wound to prevent the solidification of the resin by forming an outer body, the valve pin 210 in the nozzle 220 in the vertical direction It is a structure that is installed to achieve lifting. Here, the nozzle 220 is a resin channel 230 is formed with a predetermined gap around the valve pin 210, both ends of the resin channel 230, the outlet of the nozzle and the resin channel of the manifold 300 Each structure is connected to the 310.

In the injection molding machine valve device for the multi-cavity mold configured as described above, when a high-pressure operating pressure is selectively supplied through the air channels 110 and 120, the piston 140 moves up or down, and at the same time, the valve pin 210 is interlocked. Lifting operation is performed integrally. Therefore, as the piston 140 is elevated, the outlet of the nozzle is opened or blocked, so that the resin supplied through the manifold 300 is supplied into the mold or blocked through the outlet.

In summary, the valve gate (outlet) device for the injection molding machine operating the air pressure according to the prior art is to supply the high pressure air selectively into the cylinder 130 through the corresponding air channels (110, 120) to lift the piston (140) In this case, in conjunction with the piston 140, the valve pin 210 opens and closes the outlet of the nozzle.

However, since the valve device according to the related art configured as described above uses high pressure air as an operation source for elevating the valve pin, it is necessary to adopt an airtight structure to prevent air leakage and a large pneumatic device for supplying the working pressure. As it requires a compressor, the structure is complicated by its volume, which is not only limited to the installation space but also has a disadvantage of extremely poor maintenance and management.

In addition, when applied to a multi-cavity mold having a plurality of nozzles, due to the dimensional dispersion of each nozzle, the injection amount of each nozzle occurs as a result, there was a problem that it is difficult to mass-produce a molded article having a uniform quality.

In order to solve such a problem, the applicant has applied for utility model registration No. 2002-09883 (Registration No. 0280604, registration decision), Utility Model Registration Application No. 2002-09884 (Registration No. 0280605, Registration Maintenance Decision), utility Application for registration of utility model No. 2002-09885 (registration No. 0280606, registration maintenance decision), application for utility model registration No. 2002-19175 (registration No. 0290456, registration maintenance decision), application for utility model registration No. 2003-0034932 (registration) No. 0341515 registration maintenance decision, Utility Model Registration Application No. 2003-0038360 (Registration No. 0344137 registration maintenance decision) has been registered a valve device for operating the valve pin in the vertical direction by the power source.

Looking at the configuration of these valve apparatus roughly, it is composed of a nozzle and a driving means largely, the nozzle is a general valve structure in which a resin flow path for receiving the resin therein is injected into the mold through the outlet provided in the tip portion Take In addition, the drive means is used a forward and reverse motor or solenoid actuator for raising and lowering the valve pin by the power supply.

As described above, the applicant applies a valve device, which is applied by a power supply, to the inverted and reverse motors or actuators. As a driving source, the overall size of the valve device can be reduced, thereby increasing the degree of freedom in mold design. In addition, the valve pin movement can be controlled quickly and precisely.

However, in the case of using the stationary motor as a driving source in various valve devices, the applicant has to have a reduction gear as well as a cooling structure for cooling the motor, which is structurally complicated and economical mass production is difficult. .

On the other hand, in the case of the actuator using the solenoid principle, the structure can be relatively simplified, but there is a disadvantage in that smooth driving is not performed at the time when the valve pin moves to the relative position in the open or closed state. This is not just a solenoid actuator. In almost all hot runner systems, the valve pin is fitted to the outlet when the outlet is shut off, and the other end is fitted to the bushing to support linear movement. When the valve pin is raised to open the outlet in such a state, it is possible to overcome the stop resistance applied to the valve pin (the frictional resistance caused by the supporting element such as the bushing supporting the valve pin and the frictional resistance when it is fitted to the outlet). It needs enough power, that is, large power. That is, in most hot runner systems, a drive source with an output higher than the rated output is applied to overcome the frictional resistance initially acted upon moving to the relative position in the raised or lowered state of the valve pin and to allow the lowering or raising operation to be executed. There is a situation.

Therefore, there is not only a closed end which increases the manufacturing cost as a high output drive source (hydraulic pneumatic cylinder, forward / reverse motor, actuator) is required, but also a mold for forming a compact and precise injection molding as the volume increases. There was a problem that the degree of freedom of application is greatly limited.

In particular, there is a problem that the lifting and lowering of the valve pin is not smooth when molding a small and precise part, or when molding the product by using a resin containing glass fiber or magnesium component having poor fluidity.

In addition, the end of the nozzle is in contact with the mold to lose heat to the mold, when the resin flows to maintain the molten state by the heater wound on the outer surface of the nozzle, but when the resin flow is stopped Due to the heat loss occurring at the end, the resin in this part solidifies, resulting in the injection process having to be suspended until the solidified resin melts again, resulting in reduced productivity and the solidified resin not completely melting. There was a closed end that caused mold failure.

In order to solve this problem, conventionally, a high frequency or low pressure heating means is additionally installed to enable rapid heating of the tip of the nozzle, but due to rapid heating of the tip of the nozzle, it causes damage to the mold which is in contact with the mold. There is a serious problem of shortening.

In addition, as the high-frequency and low-pressure heating means are installed around the nozzle, the overall volume of the valve device is increased, thereby limiting the degree of freedom in design, and it is not applicable to the mold for mass production of compact and precise molded products. There is a problem in that the economy is inferior because of the difficulty of maintenance and additional equipment of expensive high frequency and low pressure equipment.

Patent Publication No. 10-2010-0119484, p. 2, Claim 1, Figure 2 The patent document 1 is a patent document published by the applicant of the present application, which is coupled to one side of the manifold in claim 1, the resin is supplied and the nozzle is provided with a valve pin for opening and closing the gate by the lifting operation in the inner center, The rotor is coupled to the other side of the manifold and is supplied with power and rotated by interaction with the stator, and the screw is screwed to the inner circumferential surface of the rotor to have a vertical displacement. In the hot runner valve device for an injection molding machine comprising a motor, the lifting screw shaft is projected to one end of the striking pin, the coupler is suppressed the rotation of the striking pin when the lifting screw shaft rotates the lifting screw shaft is vertical displacement Disclosed is a configuration in which a stop pin to have a protrusion is formed. The patent document 1 of such a structure is a structure for elevating the valve pin as mentioned above in the problem of the prior art, as the resin flows on the outer surface of the valve pin as well as poor flowability of the resin by the valve pin Since the gate is to be opened and closed, the structure is complicated, and miniaturization is difficult.

The present invention was created in order to solve the problems of the prior art as described above, and an object of the present invention is to use a temperature difference between a high temperature nozzle and a relatively low temperature mold, and a flow of resin in a lifting pin lifted in the nozzle. Hot runner valve device for injection molding machine to improve the quality and mass production of molded products by forming molding conditions for small precision parts or resins with poor fluidity without applying complicated mechanical opening and closing structure. To provide.

Another object of the present invention is to allow the lifting pins to be rotated by a predetermined angle when the lifting pins are moved upward after completion of the holding step for the cavity of the mold, resulting in twisting between the solidified resin part in the lifting pin end and the molded part in the gate of the mold. The present invention provides a hot runner valve device for an injection molding machine capable of causing shearing to separate a molded article.

Still another object of the present invention is to provide a hot runner valve device for an injection molding machine that simplifies the structure of the elevating drive element for elevating and elevating the elevating pin, thereby ensuring ease of manufacture and maintenance and enabling economical fabrication.

Hot runner valve device for an injection molding machine according to a preferred embodiment of the present invention for realizing the above object is connected to one side of the manifold to receive the resin to guide the cavity of the mold, the heater wound on the outer peripheral surface A hot runner valve device for an injection molding machine comprising: a body which is provided inside the nozzle and is elevated by an elevating drive element, and which has a reduced diameter at a lower end of the body and a body which is perforated so that resin can flow to the center thereof; It is characterized in that it is formed integrally to include a lifting pin made of a flow control tip connected to one side of the mold cavity when descending.

As a preferable feature of the present invention, the nozzle is provided with a body in which the lifting pin is slidably inserted therein and integrally provided on one side of the body to form a chamber which is an enlarged space therein and the working pressure from the outside to the side. It is provided with a cylinder portion formed with a lower air channel for receiving the supply and the cylinder cap is fitted to shield the open top of the cylinder portion, the upper end of the lifting pin is composed of a cylinder cap, the lifting pin is the cylinder cap It is provided to have a cap fitting portion which is fitted in the slide and an expanded diameter in the lower side of the cap fitting portion and to the lower side while having a reduced diameter at the lower side of the plunger portion and the lower side of the plunger portion receiving the operating pressure supplied to the chamber Flow control tip is provided on the support pipe portion and the outer circumferential surface of the support pipe portion is formed to elastically In that the upper axis element is being contact with the plunger portion and the bottom consists of a return spring, which is supported to be raised elastically lift pins are supported on a step surface formed on the inner nozzle.

In another preferred aspect of the present invention, the nozzle is provided with a body in which the lifting pin is slideably inserted therein and integrally provided on one side of the body to form a chamber which is a space in which the working pressure acts and is lowered to the side. And a cylinder cap in which each air channel for the upward movement is formed, and a cylinder cap in which the upper end of the lifting pin is slid into the center thereof while being fitted to shield the open upper portion of the cylinder portion, and the lifting pin is located at the lower side. The flow control tip is connected to the support tube formed and formed on the upper side of the support tube portion is provided with a fitting pipe portion and a guide tube portion protruding from the lower surface of the cylinder cap to the inner circumferential surface and having an expanded diameter above the fitting pipe portion The outer surface is in close contact with the inner circumferential surface of the cylinder portion is connected to each air channel chamber It is composed of a lifting plunger which is divided into a space and the lifting force is applied by the supply working pressure.

As another preferable feature of the present invention, the lifting pin is formed between the body and the flow control tip is a hollow cone-shaped flow resistance portion 31b of which the diameter is reduced toward the flow control tip, the body and the flow The control tip is in that the resin flow path and the draw path are connected to each other so that the resin can flow therein.

In another preferred aspect of the present invention, the lifting pin further includes a shearing means for causing shearing by twisting at the gate of the mold by rotating a predetermined angle after the resin injection into the cavity is completed. The lifting pin is provided to one side of the driving source for generating a driving force provided on the outer side of the cylinder and the drive gear connected to the driving source to receive the driving force and the lifting pin located in the chamber. The gear is engaged with the drive gear at the position is composed of a rotary gear that rotates in conjunction with the driving force.

The hot runner valve device for an injection molding machine according to the present invention comprises a part of the elevating drive element that provides the elevating driving force for the elevating pin integrally with the nozzle and the elevating pin, so that the structure thereof is simple, thereby increasing the reliability of the elevating operation. In addition, it is expected that the manufacturing and maintenance convenience and economical manufacturing are possible.

In addition, the end portion of the elevating pin when the elevating pin is located in the nozzle or contact with the mold by using the phenomenon that the resin therein solidifies and melts to facilitate the supply of resin injected into the cavity of the mold. have.

Therefore, the molding conditions for resins containing small precise parts or components with poor fluidity can be well established, and the structure of the driving source for driving the lifting pin can be simplified, resulting in maintenance and handling of the product. Not only can the management be improved, but the volume of the driving element can be greatly reduced, which greatly increases the degree of freedom of application and design of the mold, thereby providing a very useful effect in the industry.

The features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings. Prior to that, terms and words used in the present specification and claims should not be construed in a conventional and dictionary sense, and the inventor may properly define the concept of the term in order to best explain its invention It should be construed as meaning and concept consistent with the technical idea of the present invention.

1 is a cross-sectional view showing a hot runner valve device for an injection molding machine according to the prior art,
2 and 3 are cutaway perspective views showing the internal configuration of the hot runner valve device for an injection molding machine according to an embodiment of the present invention,
Figure 4 is an exploded perspective view of a hot runner valve device for an injection molding machine according to an embodiment of the present invention,
Figure 5 is a cross-sectional view showing a hot runner valve device for an injection molding machine according to an embodiment of the present invention,
6 to 9 are operation cross-sectional views for explaining the operation of FIG.
10 and 11 are cross-sectional view showing a hot runner valve device for an injection molding machine according to another embodiment of the present invention,
12 to 14 is a view showing a hot runner valve device for an injection molding machine according to another embodiment of the present invention,
15 is a view showing a hot runner valve device for an injection molding machine according to another embodiment of the present invention.

Hereinafter, a hot runner valve device for an injection molding machine according to the present invention will be described with reference to the accompanying drawings. First, it should be noted that the same components or parts among the drawings are denoted by the same reference numerals as possible. 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.

2 and 3 is a cutaway perspective view showing a hot runner valve device for an injection molding machine according to an embodiment of the present invention, Figure 2 shows the lifting pin is raised position, Figure 3 is the lifting pin is lowered end It is a cutaway perspective view which shows the state connected to the gate g of this metal mold | die m.

4 is a cross-sectional view illustrating the hot runner valve device for the injection molding machine of FIG. 2, wherein the nozzle 20 is installed in the nozzle installation hole m1 ′ of the upper core m ′ constituting the mold m. The nozzle 20 is largely comprised of the body 21a and the cylinder part 21b.

FIG. 5 is a cross-sectional view schematically illustrating a hot runner system to which the hot runner valve device of the injection molding machine of FIG. 2 is applied, and FIGS. 6 to 9 are cross-sectional views illustrating an operation of FIG. 2.

FIG. 6 illustrates a state in which the lifting pin 30 is moved downward by the operating pressure supplied through the falling air channel 21cp, which is one of the lifting driving elements, for filling the resin c in the cavity c of the mold m. 7 is a flow control tip 32 for forming an end of the lifting pin 30 in a state for maintaining the holding pressure in the cavity c after the filling of the cavity c of the mold m is completed. 8 is a view showing a state in which the resin staying inside the solidified state, and FIG. 8 shows the working pressure acting on the falling air channel 21cp by completing molding of the resin filled in the cavity c of the mold m. As shown in the released state, when the operating pressure acting on the falling air channel (21cp) is released, the lifting pin 30 is made to move up by the elastic support force of the return spring (40).

Finally, Figure 9 shows a state in which the solidified resin is melted in the flow control tip 32 to form the end of the lifting pin 30 is moved up.

Referring to the drawings, the configuration of the injection molding machine hot runner valve device 1 of the present invention will be described.

First, the hot runner valve device 1 for an injection molding machine of the present invention receives a resin from an injection cylinder (not shown) largely, and a manifold 10 having several branched resin furnaces 10a formed therein to branch and supply the resin. And a nozzle 20 connected to one side of the manifold 10 to inject the resin into the cavity c of the mold m formed of upper and lower cores m1 and m2. The elevating operation is controlled by the elevating drive element while being installed in the nozzle 20 so as to elevate the elevating operation, and the elevating operation is connected to the gate g which forms the inlet of the cavity c provided in the upper core m1. The pin 30 and the shear means 50 are separated from the molded article by torsional shearing after the filling of the resin in the cavity c of the mold m is completed.

The manifold 10 is manufactured in the shape of a plate made of a metal material having excellent thermal conductivity, and is formed in a branched shape of the resin path 10a through which the liquid resin in the molten state is moved. In addition, a heater (not shown) is buried so as to prevent the resin flowing along the resin path 10a from solidifying. Looking at the manifold 10 of this configuration based on the drawings, the lower side is the nozzle 20 to be described later and the elevating structure element for elevating the elevating pin 30 is provided in the inside of the nozzle 20 It is provided. Since the manifold 10 of such a structure is implemented by a well-known technique, detailed description is abbreviate | omitted.

The nozzle 20 has a tubular body 21a having a hollow cylindrical shape, a cylinder portion 21b having an enlarged size above the body 21a with reference to the drawings, and the cylinder portion 21b. It consists of a cylinder cap (21c) for shielding the open upper surface.

The body 21a is formed to penetrate the lifting pin 30 so as to slide up and down inside thereof, and a heater 23, which is a heating element that is heated by receiving power from the outside, is wound on the outer circumferential surface thereof.

The cylinder portion 21b is provided with a size having an expanded diameter on one side of the body 21a, and forms a chamber 21s therein, which is a space in which hydraulic or pneumatic operating pressures act, and on the side of the cylinder 21b. The falling air channel 21cp is formed to receive the working pressure from. At this time, the falling air channel (21cp) is connected to the working pressure to the chamber (21s).

The cylinder cap 21c is provided with a fitting to shield the open upper portion of the cylinder portion 21b, and has a structure through which a hole penetrates so that an upper end of the lifting pin 30 slides at the center thereof.

The nozzle 20 of this configuration is heated to a temperature of approximately 250 ~ 350 ℃ because the resin should be kept in a molten state, but in the case of a mold to maintain a relatively low temperature of 60 ~ 90 ℃ for the molding of the molded article In the present invention, when the lower surface of the nozzle 20 is in direct contact with the mold m, the resin fluidity at the end of the body 21a of the nozzle 20 is deteriorated as a result of a sudden heat loss. As an alternative to alleviate this, a gap is provided between the lower surface of the body 21a of the nozzle 20 and the upper core m 'constituting the mold m, or an interposed member made of a material having low thermal conductivity. It will be possible.

Reference numeral 23 denotes a temperature sensor for measuring the temperature of the nozzle 20.

On the other hand, the nozzle 20 of the configuration as described above is provided with a lifting pin 30, which will be described later into the inside of the lifting state in the slide inserted state.

The lifting pin 30 is provided inside the nozzle 20 and is lifted by the lifting driving element. The lifting pin 30 has a body 31 through which the resin supplied from the manifold 10 can flow. ) And a flow control tip 32 which is integrally formed to have a reduced diameter at the lower end of the body 31 and is connected to one side of the cavity c of the mold m when descending.

The body 31 is provided to have a tubular cap fitting portion 31c that slides into a hole formed through the center of the cylinder cap 21c, and has a diameter extended to the lower side of the cap fitting portion 31c. Support that the flow control tip 32 is connected to the lower side of the plunger portion 31b and the lower side of the plunger portion 31b and the lower side of the plunger portion 31b to receive the operating pressure supplied to the chamber 21s. The upper end is in contact with the lower surface 31b 'of the plunger portion 31b and the lower end is formed in the nozzle 20 at the end of the pipe portion 31a. It is composed of a return spring 40 which is supported by 21a 'and elastically supports so that the lifting pin 30 is raised.

10 and 11 are cross-sectional views showing a hot runner valve device for an injection molding machine according to another embodiment of the present invention, wherein the hot runner valve device for an injection molding machine in this embodiment is similar to that of the embodiment described above. . However, there is a difference in using an operating pressure of hydraulic or pneumatic pressure without using a spring as a return element for returning the lifting pin 30.

The nozzle 20 and the lifting pin 30 in the hot runner valve device for an injection molding machine according to the present embodiment are configured as follows.

The nozzle 20 is a body 21a having a tubular shape in which the elevating pin 30 is slidably inserted into and lifted from the inside, and is integrally provided at one side of the body 21a to act as a space for operating pressure therein. The chamber 21s is formed, and the cylinder portion 21b having the respective air channels 21cp and 21ce for lowering and upward movement is formed on the side surface and fitted to shield the open upper portion of the cylinder portion 21b. The center of the lifting pin 30 is composed of a cylinder cap (21c) is the upper end of the slide fitting.

The lifting pin 30 is provided at the lower side of the support pipe portion 31a to which the flow control tip 32 is connected and is connected to the upper side of the support tube portion 31a, and protrudes from the lower surface of the cylinder cap 21c to the inner circumferential surface. The fitting tube portion 31f, into which the guide tube portion 21ca is slid, has an expanded diameter above the fitting tube portion 31f, and its outer surface is in close contact with the inner circumferential surface of the cylinder portion 21b, so that the chambers 21s can be separated from each other. The lifting plunger 31d is divided into spaces 21sa and 21sb to which the air channel is connected, and the lifting force is applied by the supply working pressure.

12 to 14 is a view showing a hot runner valve device for an injection molding machine according to another embodiment of the present invention.

This embodiment is substantially the same as the configuration of the hot runner valve device for an injection molding machine described above. However, in this embodiment, when the resin filled in the cavity (c) forms a solidified article, the shear means 50 for inducing shear of the molded article and the resin in the flow control tip 32 of the lifting pin 30. Propose additionally configured features.

Shear means 50 is a drive source 51 for generating a driving force provided on the outer side of the cylinder (45a) and a drive gear connected to the drive source 51 is located in the chamber (21s) to receive the driving force ( 53) and a rotation that is provided on one side of the lifting pin 30 located in the chamber 21s and meshes with the drive gear 53 at a position where the lifting pin 30 is lowered to rotate in response to a driving force. It consists of a gear 55.

The shearing means 50 of this configuration is completed by the resin (c) in the cavity (c) after completing the resin injection pin 30 is rotated by a predetermined angle, so that at the gate (g) portion of the mold (m) A torsional shear is made between the solidified resin r 'and the molded article in the flow control tip 32 of the elevating pin 30.

15 is a view showing a hot runner valve device for an injection molding machine according to another embodiment of the present invention.

This embodiment is similar to the configuration shown in Figs. 10 and 11 described above. However, the lifting pin in the present embodiment has a feature of processing by assembling separately without integrally molding the plunger. Hereinafter, in describing the configuration of the present invention, the same reference numerals are given to the same parts as in the above-described embodiment, and in describing the configuration of the present embodiment, the description and the reference numerals will be omitted for unnecessary components.

The nozzle 20 and the lifting pin 30 in the hot runner valve device for an injection molding machine according to the present embodiment are configured as follows.

The nozzle 20 is a chamber 21s in which the lifting pins 30 are slideably inserted into and lifted from the inside, and a chamber 21s that is integrally provided at one side of the body 21a to actuate an operating pressure therein. ) And a cylinder portion (21b) formed with air channels (21cp, 21ce) for lowering and upward movement on the side, and to shield the open upper portion of the cylinder portion (21b). It comprises a cylinder cap (21c) is formed a through hole through which the resin flows.

The lifting pin 30 is provided as a straight cylindrical tube whose body 31 is shown in the figure, the upper end is inserted into the through hole formed in the center of the cylinder cap (21c), which will be described later The lift is linked with the plunger 31e.

In addition, the lifting pin 30 is integrally provided by fitting the plunger 31e to the upper end of the body 31, and the outer circumferential surface of the plunger 31e at this time is the cylinder portion 21b A gasket (unsigned) is provided on the outer circumferential surface so that the inner wall surface of the upper and lower surfaces can be lifted and in contact with the inner wall surface.

In addition, the plunger 31e is configured to partition the chamber 21s, which is the internal space of the cylinder portion 21b, into a space in which each air channel 21cp, 21ce acts, and as a result, is selective according to the supply working pressure. Received by the lifting power to achieve a vertical movement.

By the lifting force acting on the plunger 31e, the elevating pin 30 is interlocked to perform an elevating operation. Accordingly, the flow control tip 32 of the elevating pin 30 is selectively provided to the cavity of the mold. As a result of connection or movement to the inside of the nozzle, the supply of the resin is interrupted by the phenomenon that the resin inside the lifting pin is melted or solidified.

It is to be understood that the present invention is not limited to the disclosed embodiment and that various changes and modifications may be made without departing from the spirit and scope of the present invention as set forth in the appended claims. It is obvious to those who have knowledge. It is therefore intended that such variations and modifications fall within the scope of the appended claims.

1 valve device 10 manifold 10a resin
20: nozzle 23: heater 30: lifting pin
31 body 32 flow control tip 40 return spring
m: mold r: molten resin r ′: solidified resin

Claims (6)

In the hot runner valve device for injection molding machine which is connected to one side of the manifold and supplied with resin to guide the cavity of the mold, the nozzle having a heater wound on the outer peripheral surface,
It is provided inside the nozzle 20 and is elevated by an elevating drive element, and integrally formed to have a reduced diameter at the lower end of the body 31 and the lower body of the body 31 so that resin can flow to the center thereof. Lifting pin (30) consisting of a flow control tip 32, the end of which is connected at one end to the cavity (c) of the mold (m) when descending;
Hot runner valve device for injection molding machine comprising a.
The method of claim 1,
The nozzle 20 is integrally provided on one side of the body 21a and the body 21a in which the lifting pins 30 are slideably inserted therein to form a chamber which is an extended space therein, The cylinder part 21b in which the falling air channel 21cp is provided for receiving a working pressure from the outside, and it is fitted to shield the open upper part of this cylinder part 21b, and the upper end of the lifting pin 30 in the center thereof The slide cap is composed of a cylinder cap (21c),
The lifting pin 30 is provided to have a cap fitting portion 31c slide-fit to the cylinder cap 21c and an extended diameter at the lower side of the cap fitting portion 31c, and is supplied to the chamber 21s. The support pipe part 31a and the support pipe part having the reduced diameter at the lower side of the plunger part 31b and the flow control tip 32 connected to the lower side of the plunger part 31b to be lowered and interlocked under pressure. It is provided on the outer circumferential surface of 31a and elastically stretched. The upper end is in contact with the lower surface 31b 'of the plunger portion 31b, and the lower end is supported on the stepped surface 21a' formed inside the nozzle 20, and the lifting pin ( Hot runner valve device for injection molding machine, characterized in that consisting of a return spring (40) elastically supported so that 30 is raised.
The method of claim 1,
The nozzle 20 is a chamber 21s in which the lifting pins 30 are slideably inserted into and lifted from the inside of the nozzle 20 and a chamber 21s which is a space in which an operating pressure acts inside the body 21a. And a cylinder portion 21b formed with air channels 21cp and 21ce for lowering and upward movement on the side thereof, and fitted to shield an open upper portion of the cylinder portion 21b. The upper end of the lifting pin 30 is composed of a cylinder cap (21c) that is slide-fitted,
The lifting pin 30 is provided at the lower side of the support pipe portion 31a to which the flow control tip 32 is connected and is connected to the upper side of the support tube portion 31a, and protrudes from the lower surface of the cylinder cap 21c to the inner circumferential surface. The guide tube portion 21ca is fitted with a fitting pipe portion 31f to which the slide is fitted and has an expanded diameter above the fitting pipe portion 31f and its outer surface is in close contact with the inner circumferential surface of the cylinder portion 21b so as to cover the chamber 21s, respectively. Hot runner valve device for injection molding machine characterized in that the air channel is connected to the space (21sa, 21sb) is connected to the lifting plunger (31d) is applied to the lifting force by the supply operating pressure.
The method of claim 1,
The lifting pin 30 is formed between the body 31 and the flow control tip 32 is a hollow cone-shaped flow resistance portion 31b of which the diameter is reduced toward the flow control tip 32, Body 31 and the flow control tip 32 is a hot runner valve device for injection molding machine, characterized in that the resin flow path (30a) and the take-out passage (32sh) are connected to each other so that the resin can flow into the interior.
4. The method according to claim 2 or 3,
The elevating pin 30 further includes a shearing means 50 which rotates by a predetermined angle after the resin injection into the cavity c is completed, thereby causing shearing by twisting at the gate g of the mold m. ,
The front end means 50 is a drive source 51 for generating a driving force provided on the outer side of the cylinder (45a) and a drive gear connected to the drive source 51 is connected to the drive source 51 to receive the driving force 53 and a gear that is provided on one side of the lifting pin 30 located in the chamber 21s and meshes with the drive gear 53 at a position where the lifting pin 30 is lowered to rotate in response to a driving force. Hot runner valve device for injection molding machine, characterized in that consisting of a rotary gear (55).
The method of claim 1,
The nozzle 20 is a chamber 21s in which the lifting pins 30 are slideably inserted into and lifted from the inside of the nozzle 20 and a chamber 21s which is a space in which an operating pressure acts inside the body 21a. And a cylinder portion 21b having respective air channels 21cp and 21ce for lowering and upward movement on the side thereof and shielding the open upper portion of the cylinder portion 21b. It consists of a cylinder cap (21c) formed with a through hole to flow,
The body 31 of the elevating pin 30 is provided with a straight pipe so that the upper end thereof is slide-inserted into the cylinder cap 21c,
One end of the elevating pin 30 is assembled by a fitting coupling, and the elevating interlocking unit is integrated. The outer circumferential surface thereof is in sliding contact with the inner wall surface of the cylinder portion 21b, and each air channel is connected to the chamber 21s. Plunger 31e which is partitioned into the space and selectively lifted by the supply working pressure
Hot runner valve device for injection molding machine comprising a.

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