KR20220097799A - IMG mold for component of vehicle - Google Patents

Abstract

The present invention relates to an in mold graining (IMG) mold device for components of a vehicle, which comprises: IMG fabric heated to mold a component of a vehicle; an upper mold moving vertically in order to mold the IMG fabric; a lower mold disposed under the upper mold to face the upper mold in a vertical direction and interlinked to the upper mold to move vertically, so that the lower mold is combined with the upper mold to mold the IMG fabric; a cavity formed on an upper surface of the lower mold to mold a heated injected material of the IMG fabric through combination between the upper mold and the lower mold; an undercut unit where the heated IMG fabric is not pressurized by combination between the upper mold and the lower mold according to the shape of the injected material molded by the cavity; and a main pressurization unit installed on the upper mold to be adjacent to the undercut unit to selectively pressurize the undercut unit in a direct way when the upper mold is combined with the lower mold. Accordingly, convenient and compact structure design maximizes space utilization to promote miniaturization, thereby enhancing convenience of a worker.

Description

IMG mold for automobile parts {IMG mold for component of vehicle}

The present invention relates to an IMG mold apparatus for automobile parts, and more particularly, by directly pressing the undercut part through the main pressing unit, and indirectly pressing the undercut part by the sub pressing unit if necessary, the IMG fabric is molded through a cavity IMG molds for automobile parts that can improve the manufacturing process of injection-molded products, increase the durability of the injection-molded products through increased adhesion, increase quality, reduce IMG molding costs, promote operator convenience, and maximize safety and reliability It's about the device.

The interior materials of automobiles are composed of various products such as door trims, bumpers, consoles, and seats. Among the interior materials of automobiles, door trim improves the aesthetics of the interior of the vehicle, provides a comfortable and comfortable driving space for passengers, protects the driver and passengers from external shocks that may occur while driving, and installs various storage spaces, safety equipment, and electronic equipment. It is a space, and since it is a space where the user's arms or legs can be adjacent to each other, it is possible to further improve the user's satisfaction by improving the soft feeling.

In recent years, as the interior materials of automobiles have become more advanced, in-mold graining (IMG) has been introduced as a molding method for interior materials of automobiles, which is a part of automobile parts.

Such IMG molding enables the surface treatment of more luxurious interior materials by using a mold (electroforming mold) with a sophisticated pattern or texture through electroforming.

However, in the conventional IMG mold device for automobile parts, the undercut part, which is a concave part in which it is difficult to discharge the injection product, is formed inside the injection mold only in the closing or opening direction of the injection mold, making accurate molding impossible and the adhesive force is reduced, so the quality of the injection product is reduced. There was a problem in that this was lowered and reliability and stability were lowered.

In addition, as the conventional IMG mold apparatus for automobile parts uses a forced extraction method in which the mold is forcibly taken out of the injection molded product, the shape of the injection product is deformed or scratched, resulting in reduced durability and defective products due to deterioration of appearance quality This increase causes resource wastage, increases production cost, and ultimately increases the unit price of the final injection product, resulting in consumer dissatisfaction.

Furthermore, as the conventional IMG mold device undercut for automobile parts is subjected to only indirect pressurization like the suction method, the molding performance decreases or the productivity decreases as the molding time becomes longer, and the maintenance cost increases due to the maintenance of the suction device and long-term use In addition, there was a problem that caused inconvenience to workers and caused safety accidents.

In addition, in the conventional IMG mold device for automobile parts, the product quality is deteriorated as the undercut part is not accurately removed according to the complex structure and design, and the IMG mold cannot be miniaturized, resulting in a decrease in exports due to an increase in manufacturing cost. , space utilization is reduced, productivity is reduced due to the increase in work process and time, and the cost of automobile parts is increased due to waste of IMG fabrics .

Accordingly, the undercut part is directly pressurized first and, if necessary, the undercut part is secondarily indirectly pressed to form the undercut part effectively to improve the molding quality, reduce productivity and production cost, and maximize the satisfaction of workers and consumers. However, there is an urgent need to develop an IMG mold device for automobile parts that can improve safety and reliability.

Korean Patent Publication No. 10-2015-0110930 Korean Patent Registration Publication No. 10-1850746 Korean Patent Dongreuk Publication No. 10-2036129 Korean Patent Dongreuk Publication No. 10-1959316 Korean Patent Registration Publication No. 10-1567382

The present invention is to solve the above problems, and an object of the present invention is to directly pressurize the undercut part by expanding the expansion part of the main pressing unit when the upper mold and the lower mold are press-merged, and the type of injection product or type of IMG fabric By indirectly pressurizing the undercut part by vacuum suctioning the sub-pressurizing unit as needed, such as ingredients, etc., the manufacturing process of the injection molded product molded through the cavity with IMG fabric is improved, and the durability of the injection product is improved by increasing the adhesion of the undercut part to improve quality. After accurately calculating the amount of expansion of the inflatable part and the suction amount of the suction part in real time according to the type of IMG fabric, component, and type of injection product, the undercut part is first directly pressurized through the expansion part with the most effective pressure, and then through the suction part. Secondary indirect pressurization reduces injection molding cost and time to improve productivity, reduce maintenance costs, and prevent unnecessary waste and defective products in IMG fabrics in advance to protect resources and reduce production costs. to improve customer satisfaction, an optimized structure such as arranging the main pressing unit in the upper mold adjacent to the undercut part and the sub pressing unit in the lower mold adjacent to the undercut part, and a simple and compact structure through the expansion and suction part To provide an IMG mold device for automobile parts that maximizes space utilization through design to achieve miniaturization, improve operator convenience, promote operator convenience, and improve safety and reliability.

In order to achieve the object of the present invention, the IMG mold apparatus for automobile parts according to an embodiment of the present invention is an IMG mold apparatus for automobile parts for molding automobile parts, wherein the IMG mold apparatus for automobile parts molds automobile parts IMG fabric to be heated for; an upper mold that elevates and descends to shape the IMG fabric; a lower mold disposed under the upper mold to face each other in the height direction with the upper mold and configured to form the IMG fabric through merging with the upper mold as it elevates and lowers in conjunction with the upper mold; a cavity formed on the upper surface of the lower mold to mold the injection product of the IMG fabric heated through the merging of the upper mold and the lower mold; an undercut part in which the IMG fabric heated according to the shape of the injection molded product by the cavity is not pressed by the merging of the upper mold and the lower mold; and a main pressing unit installed in the upper mold adjacent to the undercut part to selectively and directly press the undercut part when the upper mold and the lower mold are merged.

In addition, in a preferred embodiment of the IMG mold apparatus for automobile parts according to the present invention, the IMG mold apparatus for automobile parts is installed in the lower mold so as to be adjacent to the undercut portion, and the pressurization is performed when the upper mold and the lower mold are merged. It may further include a; sub-pressing unit for selectively indirectly pressing the undercut portion in conjunction with the unit.

In addition, in a preferred embodiment of the IMG mold apparatus for automobile parts according to the present invention, the IMG mold apparatus for automobile parts includes the undercut part when molding an injection product with the IMG fabric heated by merging the upper mold and the lower mold. It may further include; a control unit for controlling the operation status and operation order of the main pressurizing unit and the sub-pressurizing unit and the direct pressurization amount and the indirect pressurization amount of the undercut part in order to pressurize.

In addition, in a preferred embodiment of the IMG mold apparatus for automobile parts according to the present invention, the main pressing unit of the IMG mold apparatus for automobile parts includes a receiving part formed in the upper mold to be adjacent to the undercut part; an expansion unit disposed inside the receiving unit, expanded by pneumatic or hydraulic pressure supplied according to a control signal of the control unit, and directly pressurizing the undercut unit through contact with the undercut unit; a pressure supply unit for supplying an expansion pressure to the expansion unit; and a flow path part having one side connected to the expansion unit and the other side connected to the pressure supply unit to transmit the expansion pressure supplied from the pressure supply unit to the expansion unit.

Further, in a preferred embodiment of the IMG mold apparatus for automobile parts according to the present invention, the sub-pressing unit of the IMG mold apparatus for automobile parts is disposed on the lower mold to be adjacent to the undercut portion, and according to a control signal of the controller, the a suction unit for vacuum-sucking the undercut unit and indirectly pressurizing the undercut unit with the expansion unit; and a suction unit supplying suction pressure to the suction unit.

In addition, in a preferred embodiment of the IMG mold apparatus for automobile parts according to the present invention, the control unit of the IMG mold apparatus for automobile parts is basic for storing data on IMG fabric information, cavity information, injection molding program, and undercut part information data storage unit; a determination unit for determining whether the main pressurizing unit and the sub-pressurizing unit are operated or not and the operation order of the main pressurizing unit through the data stored in the basic data storage unit when the upper mold and the lower mold are merged; a calculation unit for calculating the suction amount of the suction unit to adjust the expansion amount of the inflatable part and the indirect pressurization amount of the undercut part to adjust the direct pressurization amount of the undercut part according to the determination result of the basic data storage unit and the determination unit; and a command unit for operating the expander and the suction unit in a state in which the expansion amount of the expander and the suction amount of the suction unit are adjusted according to the determination result of the determination unit and the calculation result of the calculation unit.

In addition, in a preferred embodiment of the IMG mold apparatus for automobile parts according to the present invention, the control unit of the IMG mold apparatus for automobile parts includes the expansion part operated by the command signal of the command part and the undercut part according to the operation of the suction part. The feedback data for the direct pressurization amount and the indirect pressurization amount are stored in real time, and the feedback data and the calculation result of the calculation unit are compared and analyzed in real time to change the inflation amount of the inflation part and the suction amount of the suction part in real time to directly change the undercut part a correction unit for correcting the pressurization amount and the indirect pressurization amount in real time; and a display unit displaying the results of the determination unit, the calculation unit, the command unit, and the correction unit.

The IMG mold apparatus for automobile parts according to the present invention expands the expansion part of the main pressing unit when the upper mold and the lower mold are press-merged to directly press the undercut part, and serves as a sub according to the need, such as the type of injection product or the type and component of the IMG fabric. By indirectly pressurizing the undercut part by vacuum suction through the suction part of the pressurization unit, the manufacturing process of the injection molded product molded through the cavity with IMG fabric is improved, and the durability of the injection product is improved by increasing the adhesion of the undercut part, thereby improving the quality. have.

In addition, in the IMG mold apparatus for automobile parts according to the present invention, when the upper mold and the lower mold are press-merged, the expansion amount of the expansion part of the main pressing unit and the suction amount of the suction part of the sub-pressurization unit are measured by the type of IMG fabric, the component, and the type of injection product. After accurate calculation in real time according to It has the effect of improving productivity, reducing maintenance costs, protecting resources by preventing unnecessary waste of IMG fabrics and occurrence of defective products in advance, and reducing production cost to improve customer satisfaction.

Furthermore, the IMG mold apparatus for automobile parts according to the present invention has an optimized structure such as arranging the main pressing unit in the upper mold adjacent to the undercut part and the sub pressing unit in the lower mold adjacent to the undercut part, and the expansion and suction parts Through the simple and compact structure design, it is possible to maximize space utilization and achieve miniaturization, thereby increasing space utilization, reducing the manufacturing cost of IMG mold equipment, and improving safety and reliability.

In addition, the IMG mold apparatus for automobile parts according to the present invention has the effect of improving the satisfaction of consumers and promoting export, improving fuel efficiency of automobiles and promoting environmental protection through weight reduction of injection products, which are automobile parts.

1 to 3 show a conceptual diagram of a process of molding an injection product from an IMG fabric by press-merging an upper mold and a lower mold of the IMG mold device for automobile parts according to the present invention.
4 is a detailed view of a part A of FIG. 3 and shows a conceptual diagram for explaining an undercut part.
5 to 6 are conceptual views illustrating a molding process of the undercut part of the IMG mold apparatus for automobile parts according to an embodiment of the present invention in part A of FIG. 3 .
7 shows a conceptual diagram of an IMG mold apparatus for automobile parts according to an embodiment of the present invention.
FIG. 8 is a conceptual diagram illustrating operating states of the main pressing unit and the sub pressing unit of the IMG mold apparatus for automobile parts of the present invention shown in FIG. 7 .
9 is a block diagram of the control unit of the IMG mold apparatus for automobile parts according to the present invention.

Hereinafter, with reference to the drawings of the IMG mold apparatus for automobile parts according to an embodiment of the present invention will be described in detail. The embodiments introduced below are provided as examples so that the spirit of the present invention can be sufficiently conveyed to those skilled in the art. Accordingly, the present invention is not limited to the embodiments described below and may be embodied in other forms. And, in the drawings, the size and thickness of the device may be exaggerated for convenience. Like reference numbers refer to like elements throughout.

Advantages and features of the present invention, and a method for achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in a variety of different forms, only these embodiments allow the disclosure of the present invention to be complete, and common knowledge in the technical field to which the present invention pertains It is provided to fully inform the possessor of the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout. The sizes and relative sizes of layers and regions in the drawings may be exaggerated for clarity of description.

The terminology used herein is for the purpose of describing the embodiments, and thus is not intended to limit the present invention. In this specification, the singular also includes the plural unless specifically stated otherwise in the phrase. As used herein, "comprise" and/or "comprising" refers to the presence of one or more other components, steps, operations and/or elements mentioned. or addition is not excluded.

1 to 3 show a conceptual diagram of a process of molding an injection product from an IMG fabric by press-merging an upper mold and a lower mold of the IMG mold device for automobile parts according to the present invention. 4 shows a conceptual diagram for explaining the undercut part in a detailed view of part A of FIG. 3 , and FIGS. 5 to 6 are the molding of the undercut part of the IMG mold apparatus for automobile parts according to an embodiment of the present invention of part A of FIG. 3 . A conceptual diagram of the process is shown. 7 is a conceptual diagram of an IMG mold apparatus for automobile parts according to an embodiment of the present invention, and FIG. 8 is an operation state of the main pressing unit and the sub pressing unit of the IMG mold apparatus for automobile parts of the present invention shown in FIG. shows a conceptual diagram for 9 is a block diagram of the control unit of the IMG mold apparatus for automobile parts according to the present invention.

Definitions of terms used below are as follows. "Horizontal direction" means a longitudinal direction in the same member in a horizontal direction, "vertical direction" means a vertical direction in the same member while being perpendicular to the longitudinal direction, and "height direction" means orthogonal to a horizontal direction and a vertical direction It means the up-down direction in the same member. In addition, upper (upper) means an upward direction in "height direction", and downward (lower) means a downward direction in "height direction". “One side (one end)” and “the other end” refer to either end of the same member in a horizontal direction, a vertical direction, or a height direction. In addition, the inside (inside) means the direction from each same member toward the center of the same member, and the outside (outside) means the opposite part of the inside, that is, the outside.

An IMG mold apparatus 1 for automobile parts according to the present invention will be described with reference to FIGS. 1 to 9 . 1 to 9, the IMG mold apparatus 1 for automobile parts according to the present invention includes an IMG fabric 10, an upper mold 20, a lower mold 30, an undercut part 40, and a cavity ( 50 ), a main pressurizing unit 60 , a sub-pressurizing unit 70 , and a control unit 80 .

The IMG fabric 10 is heated to form an automobile part. That is, it can be heated through the upper and lower molds, and can be heated through pre-heating before the press merging of the upper and lower molds. In addition, these IMG fabrics are polypropylene (PP), polyethylene (PE), polyarimide (PA), polycarbonate (PC), polybutalene terephthalate (PBT), polyethylene terephthalate (PET), polyphenylene oxide (PPO), polyphenylene ether (PPE), polyether imide (PEI) is formed of any one or a combination of two or more. In addition, IMG fabric is superlite formed by any one of MC (sheet molding compound), GMT (glass fiber reinforced thermoplastics), LFT (Long Fiber Thermoplastics), CFRTPC (Continuous Fiber Reinforced ThermoPlastic Composite) or a composite of two or more thereof. material may be formed. However, according to the most preferred embodiment of the present invention, the IMG fabric is formed of TPO (THERMOPLASTIC OLEFINE) and polypropylene (PP) foam (FOAM).

The upper mold 20 is raised and lowered through an ejector or the like to mold the IMG fabric.

The lower mold 30 is disposed under the upper mold to face each other in the height direction. In addition, the lower mold 30 forms the IMG fabric through merging with the upper mold as it elevates and descends in conjunction with the upper mold.

The cavity 50 is formed on the upper surface of the lower mold to mold an injection product of the heated IMG fabric through the merging of the upper and lower molds.

That is, for the upper and lower molds, only the upper mold is raised and lowered through an ejector, etc. with the lower mold fixed, or only the lower mold is raised and lowered through an ejector, etc., with the upper mold fixed, or the upper and lower molds are All of them can be raised and lowered through ejectors, etc., and through press merging through elevating and lowering of the upper and lower molds, the IMG fabric is vacuum adsorbed to mold the injection molded product according to the cavity.

The undercut part 40 means a portion where the heated IMG fabric is not pressed by the merger of the upper and lower molds according to the shape of the injection molded product by the cavity. That is, as shown in FIGS. 3 to 8 , the undercut part 40 is a concave part where molding of the IMG fabric is not well performed during press merging or separation according to the elevation of the upper and lower molds. It is determined according to the shape of the cavity that is the base for forming such an injection product. For example, in FIGS. 3 to 8 , as the shape of the injection product is formed in a shape in which the lower right side is bent, the relatively weak right bending part is determined as the undercut part when the upper mold and the lower mold are press-merged.

The main pressing unit 60 is installed in the upper mold so as to be adjacent to the undercut part, and selectively directly presses the undercut part when the upper mold and the lower mold are press-merged. That is, when direct pressurization of the undercut part is required, the main pressurizing unit 60 firstly expands and pressurizes directly through contact with the undercut part, and if necessary, the main pressurizing unit uses the injection molded product to reduce process time and improve productivity. If it is not judged to be defective according to the shape of the cavity and the shape of the cavity, the undercut part may not be pressed directly.

The sub-pressurizing unit 70 is installed in the lower mold so as to be adjacent to the undercut part and selectively indirectly presses the undercut part by interlocking with the pressing unit at the time of press merging of the upper mold and the lower mold. That is, the sub-pressurizing unit 70 requires molding precision depending on the shape of the cavity or the shape of the injection product or the type of injection product and the performance or type of automobile parts, or when maximization of durability and product quality is required for various reasons, the undercut part will be described later. The suction part sucks in and indirectly presses the undercut part together with the expansion part. In addition, if necessary, the undercut part may be directly pressed and not indirectly pressed primarily by the expansion part of the main pressurizing unit. It is possible to reduce manufacturing cost and time, maximize productivity, reduce maintenance costs, promote operator convenience, and maximize molding quality and durability of injection moldings by performing only indirect pressurization by inhaling the undercut part through the

The control unit 80 controls whether or not the main pressurizing unit and the sub pressurizing unit operate and the operation order of the main pressurizing unit and the sub pressurizing unit to pressurize the undercut part when molding an injection product with the IMG fabric heated by the merger of the upper and lower molds, and the direct pressurization amount and indirect value of the undercut part. Control the amount of pressurization.

In this way, the IMG mold device for automobile parts according to the present invention expands the expansion part of the main press unit when the upper mold and the lower mold are press-merged to directly press the undercut part, and the type of injection product or the type and component of the IMG fabric are required. As a result, vacuum is sucked into the suction part of the sub-pressurizing unit and the undercut part is indirectly pressurized to improve the manufacturing process of the injection molded product molded through the cavity with the IMG fabric, and the durability of the injection molded product can be improved by increasing the adhesion of the undercut part. .

5 to 8, the main pressurizing unit 60 of the IMG mold apparatus 1 for automobile parts according to the present invention includes a receiving part 61, an expanding part 62, a flow path part 63, and It includes a pressure supply unit (64).

The accommodating part 61 is formed inside the upper mold so as to be adjacent to the undercut part.

The inflatable part 62 is disposed inside the receiving part. In addition, the expansion part 62 is expanded by pneumatic or hydraulic pressure supplied according to a control signal from the controller to directly press the undercut part through contact with the undercut part. That is, the expansion part is formed in the form of an expansion tube and is expanded by pneumatic or hydraulic pressure to directly press the undercut part when the upper mold and the lower mold are press-merged as the volume increases.

The pressure supply unit 64 supplies an expansion pressure to the expansion unit. Although not necessarily limited thereto, the pressure supply unit 64 is formed of a pneumatic pressure or a pneumatic pump or a hydraulic pump installed outside the upper mold to store pneumatic or hydraulic pressure therein.

One side of the flow path 63 is connected to the expansion unit, and the other side of the flow path unit is connected to the pressure supply unit. Accordingly, the expansion pressure supplied from the pressure supply unit is transmitted to the expansion unit by the flow path unit.

5 to 8 , the sub-pressurizing unit 70 of the IMG mold apparatus 1 for automobile parts according to the present invention includes a suction unit 71 and a suction unit 72 .

The suction part 71 is disposed in the lower mold so as to be adjacent to the undercut part. In addition, the suction unit 71 vacuum-sucks the undercut part according to a control signal from the controller to indirectly pressurize the undercut part in conjunction with the expansion part. That is, the suction part 71 is formed in the form of a suction flow path passing through a part of the lower mold, and indirectly pressurizes the undercut part by adsorbing the undercut part according to the suction pressure of the seat part. In addition, if necessary, a plurality of the suction parts may be formed in the lower mold to be adjacent to the undercut part.

The suction unit 72 serves to supply suction pressure to the suction unit. Although not necessarily limited thereto, the suction unit 72 is formed of an air suction pump installed outside the lower mold.

Therefore, the IMG mold apparatus for automobile parts according to the present invention has an optimized structure such as arranging the main pressing unit in the upper mold adjacent to the undercut part and the sub-pressurizing unit in the lower mold adjacent to the undercut part, and the expansion part and the suction part. Through the simple and compact structure design through It is possible to improve the fuel efficiency of automobiles and protect the environment by reducing the weight of injection-molded parts, which are automobile parts.

As shown in FIG. 9 , the control unit 80 of the IMG mold apparatus 1 for automobile parts according to the present invention includes a basic data storage unit 81 , a determination unit 82 , a calculation unit 83 , and a command unit 84 . ), a correction unit 85 , and a display unit 86 .

In addition, although not shown in the drawings, the control unit of the IMG mold apparatus for automobile parts according to the present invention includes a numerical control unit and a PLC.

The numerical control unit includes NC (numerical control, NC) or CNC (computerized numerical control), and various numerical control programs are built-in. That is, the upper mold driving unit, the lower mold driving unit, the main pressing unit, the sub pressing unit, and the injection molding program are built in the numerical control unit, and the program is automatically loaded and operated according to the driving of the numerical control unit. In addition, the numerical control unit communicates with the PLC and the control unit by a predetermined protocol.

In addition, although not shown in the drawings, according to a preferred embodiment of the present invention, the numerical control unit includes a main operation unit, and the main operation unit includes a screen display program and a data input program according to screen display selection, and the screen According to the output of the display program, a software switch is displayed on the display screen, and the ON/OFF of the software switch is recognized to give an input/output command for machine operation.

In addition, although not necessarily limited thereto, the casting unit includes a monitor that is installed on the outer housing, the case, or one side of the IMG mold apparatus to display various function switches or buttons and various information.

A programmable logic controller (PLC) performs communication according to a predetermined protocol with an upper mold driving unit, a lower mold driving unit, a main pressing unit, and a sub pressing unit, and performs a function of executing a control command through such communication. That is, the PLC drives the upper mold driving unit, the lower mold driving unit, the main pressing unit, and the sub pressing unit according to the numerical control unit and the numerical control program of the control unit.

In addition, the controller may provide a human-machine interface for inputting various data.

The basic data storage unit 81 stores data on IMG fabric information, cavity information, injection molding program, and undercut information. That is, the basic data storage unit stores various information of the IMG fabric, such as the component, length, thickness, and tensile strength of the IMG fabric. It stores information about the degree of importance and the degree of molding precision. In addition, information about the undercut part is stored through the cavity information and the injection molding information. The basic data storage unit 81 may be various storage devices such as ROM, RAM, EPROM, flash drive, hard drive, etc., and may be a web storage that performs a storage function of the basic data storage unit on the Internet. may be

The determination unit 82 determines whether or not the operation of the main pressing unit and the sub pressing unit and the operation order through the data stored in the basic data storage unit when the upper mold and the lower mold are merged. That is, the main pressing unit may directly press the undercut part firstly and the sub press unit may secondarily press the undercut part indirectly by the determination unit. In addition, if necessary, only the main pressing unit may primarily directly press the undercut portion or the sub-pressurization unit may primarily press the undercut portion indirectly.

The calculator 83 calculates the suction amount of the suction part to adjust the expansion amount of the expansion part and the indirect pressurization amount of the undercut part in order to adjust the direct pressurization amount of the undercut part according to the judgment result of the basic data storage part and the judgment part.

The command unit 84 operates the expansion unit and the suction unit in a state in which the expansion amount of the expansion unit and the suction amount of the suction unit are adjusted according to the determination result of the determination unit and the calculation result of the calculation unit. That is, when the calculation unit 83 directly presses the undercut part through the expansion part or indirectly pressurizes it through the suction part, it is possible to calculate and accurately pressurize the pressure amount optimized for various types of undercut parts according to the type of cavity and the type of injection product. have.

Accordingly, in the IMG mold apparatus for automobile parts according to the present invention, when the upper mold and the lower mold are press-merged, the expansion amount of the expansion part of the main pressing unit and the suction amount of the suction part of the sub-pressurization unit are measured by the type of IMG fabric, the component, and the type of injection product. After accurate calculation in real time according to It can improve productivity, reduce maintenance costs, protect resources by preventing unnecessary waste of IMG fabrics and occurrence of defective products in advance, and at the same time improve customer satisfaction by reducing production cost.

The correction unit 85 stores in real time feedback data on the direct pressurization amount and the indirect pressurization amount of the undercut part according to the operation of the expansion unit and the suction unit operated by the command signal of the command unit, and displays the feedback data and the calculation result of the calculation unit in real time. The direct and indirect pressurization amount of the undercut part is corrected in real time by comparing and analyzing the expansion amount of the expansion part and the suction amount of the suction part in real time.

That is, through the correction unit, the amount of direct pressurization and indirect pressurization of the undercut part, as well as the presence or absence of direct or indirect pressurization of the undercut part, are adjusted to the most optimized state according to the processing conditions, the type and condition of the cavity and the injection product. Accordingly, it is possible to maximize the molding quality of the injection molded product and minimize the occurrence of defective products, thereby reducing the injection molding cost, preventing resource waste, improving the stability, reliability and durability of the injection molding product, and reducing the manufacturing time to maximize productivity.

The display unit 86 displays the results of the judgment unit, the calculation unit, the command unit, and the correction unit. The display unit 86 includes a liquid crystal display (LCD), a thin film transistor-liquid crystal display (TFT LCD), an organic light-emitting diode (OLED), and a flexible display (Flexible Display). display), a three-dimensional display (3D display), and an electronic ink display (e-ink display) may include at least one. In addition, although not necessarily limited thereto, the display unit may be installed on the housing, the case, or one side of the IMG mold apparatus to display various function switches or buttons and various information.

In this way, the IMG mold device for automobile parts according to the present invention is a pre-heated IMG fabric that press-merged the upper and lower molds while vacuum adsorbing the IMG fabric to form the IMG fabric components and types, the cavity and the injection molded material. Predict where the undercut will be formed according to various conditions such as the type and type of parts used in automobiles, molding accuracy and precision, etc. When it is necessary to first directly pressurize the undercut part through direct contact with the undercut part by expanding the expanded part to the calculated expansion amount calculated in real time, and secondarily indirectly pressurize the undercut part through calculation according to the control of the controller By operating the suction part at the calculated suction amount, the undercut part is secondarily indirectly pressurized through vacuum adsorption to improve the processing quality, and finally, by adjusting the pressure amount and strength of the undercut part, the molding quality is maximized through perfect molding of the undercut part. At the same time, by minimizing molding time and molding cost, productivity can be improved, injection molding cost can be reduced, and customer satisfaction can be maximized.

In the detailed description of the present invention described above, although it has been described with reference to preferred embodiments of the present invention, those skilled in the art or those having ordinary knowledge in the technical field of the present invention described in the claims to be described later It will be understood that various modifications and variations of the present invention can be made without departing from the spirit and scope of the present invention. Accordingly, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification, but should be defined by the claims.

1: IMG mold device for automobile parts
10: IMG fabric
20: prize money
30: lower mold
40: undercut part
50: cavity
60: main pressure unit
61: receiving part
62: expansion part
63: Euro
64: pressure supply unit
70: sub pressure unit
71: suction part
72: suction unit
80: control unit
81: basic data storage unit
82: judgment unit
83: calculator
84 : Command
85: correction unit
86: display

Claims (7)

In the IMG mold apparatus for automobile parts for molding automobile parts, the IMG mold apparatus for automobile parts comprises:
IMG fabric heated to form automotive parts;
an upper mold that elevates and descends to shape the IMG fabric;
a lower mold disposed under the upper mold to face each other in the height direction with the upper mold and configured to form the IMG fabric through merging with the upper mold as it elevates and lowers in conjunction with the upper mold;
a cavity formed on the upper surface of the lower mold to mold an injection product of the IMG fabric heated through the merging of the upper mold and the lower mold; and
an undercut part in which the IMG fabric heated according to the shape of the injection molded product by the cavity is not pressed by the merger of the upper mold and the lower mold;
and a main pressing unit installed in the upper mold adjacent to the undercut part to selectively and directly press the undercut part when the upper mold and the lower mold are merged.
According to claim 1,
A sub-pressurizing unit that is installed in the lower mold adjacent to the undercut and selectively indirectly presses the undercut by interlocking with the pressing unit when the upper and lower molds are merged; IMG mold equipment for parts.
3. The method of claim 2,
When molding an injection product with the IMG fabric heated by the merging of the upper mold and the lower mold, the operation status and operation sequence of the main pressurizing unit and the sub pressurizing unit to press the undercut part, and the amount of direct pressurization of the undercut part And a control unit for controlling the indirect pressurization amount; IMG mold apparatus for automobile parts, characterized in that it further comprises.
4. The method of claim 3,
The main pressure unit is
a receiving portion formed in the upper mold to be adjacent to the undercut portion;
an expansion unit disposed inside the accommodation unit, expanded by pneumatic or hydraulic pressure supplied according to a control signal of the control unit, and directly pressurizing the undercut unit through contact with the undercut unit;
a pressure supply unit for supplying an expansion pressure to the expansion unit; and
and a flow path part connected to the expansion part on one side and connected to the pressure supply part on the other side to transmit the expansion pressure supplied from the pressure supply part to the expansion part.
5. The method of claim 4,
The sub-pressurizing unit,
a suction part disposed on the lower mold adjacent to the undercut part to vacuum suction the undercut part according to a control signal from the controller to indirectly pressurize the undercut part in conjunction with the expansion part; and
IMG mold apparatus for automobile parts comprising a; a suction unit for supplying suction pressure to the suction unit.
6. The method of claim 5,
The control unit is
IMG fabric information, cavity information, an injection molding program, and a basic data storage unit for storing data about the undercut part information;
a determination unit that determines whether the main pressurizing unit and the sub pressurizing unit are operated or not and the operation order of the main pressurizing unit through the data stored in the basic data storage unit when the upper die and the lower die are merged;
a calculation unit for calculating the suction amount of the suction unit to adjust the amount of expansion of the expansion unit and the amount of indirect pressure of the undercut unit to adjust the amount of direct pressurization of the undercut unit according to the determination result of the basic data storage unit and the determination unit; and
according to the determination result of the determination unit and the calculation result of the calculation unit, a command unit for operating the inflation unit and the suction unit in a state in which the expansion amount of the expansion unit and the suction amount of the suction unit are adjusted; IMG mold equipment.
7. The method of claim 6,
The control unit is
The feedback data for the direct pressurization amount and the indirect pressurization amount of the undercut part according to the operation of the inflating part and the suction part operated by the command signal of the command part are stored in real time, and the feedback data and the calculation result of the calculation part are stored in real time a compensator for compensating in real time the direct pressurization amount and the indirect pressurization amount of the undercut part by comparing and analyzing the expansion amount of the expansion part and the suction amount of the suction part in real time; and
The IMG mold apparatus for automobile parts further comprising a; a display unit for displaying results of the determination unit, the calculation unit, the command unit, and the correction unit.

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