KR20230146708A - Container blow molding automation system and molding method - Google Patents

Abstract

The present invention relates to a device for manufacturing containers using blow and automatic replacement of blow molds, and more specifically, to a preform injection unit that melts raw materials and then injects them from an injection mold into a molded body to form a preform, and in the preform injection unit. A preform discharging robot for discharging the injected preform, a preform alignment part for receiving and supplying the preform injected from the preform discharging robot, a blow molding mold part for receiving supply from the preform aligning part and performing blow molding, and the blow molding mold part. A container discharging unit for removing the molded container from the container, a rotary exchange mold part installed on one side of the container discharging unit to replace the forming mold of the blow molding mold part, and a replacement mold part provided in the rotary exchange mold part. It relates to a blow molding automation system and molding method for a container configured to transfer the mold to the blow mold with a mold transfer lift.

Description

{Container blow molding automation system and molding method}

The present invention relates to a device for manufacturing containers using blow and automatic replacement of blow molds. More specifically, when manufacturing synthetic resin containers or PET containers by blow, everything from the preform, which is the basic molding product of the container, to blow molding can be performed automatically. At the same time, it relates to a container blow molding automation system and molding method with artificial intelligence (AI) function so that the mold suitable for the container specifications can be automatically replaced when the blow mold (mold) is replaced.

In general, a blow molding device heats a preform, stretches it using a stretching rod, and blows compressed air to form a hollow container.

For example, a stretch blow molding device is known as a device for manufacturing hollow containers made of synthetic resin, such as plastic containers. This stretch blow molding device generally molds preforms, which are basic products. In order to blow mold this preform using air, a blow mold is formed using a rotating table while the neck of the preform is supported. The hollow container is blow molded by stretching the preform within the blow mold using a stretching rod and sending high-pressure air into the preform through a blow core mold that blocks the entrance. Accordingly, a hollow container of a desired shape can be formed.

The blow molding device as described above has the inconvenience that only some processes are automated and the remaining parts must be manually managed by humans.

In other words, after molding the preform, which is a basic molding product, it is done manually to move it to the blow molding line. Additionally, to blow mold a small container after blow molding a wide-mouth container, a blow mold (mold) is used. There is a problem in that replacement time is delayed because each product has to be replaced manually, which reduces productivity.

Looking at the prior art in this field, the container manufacturing device of Patent Registration No. 10-1585152 (registration date January 7, 2016) uses a resin material to form a container, as shown in Figure 1. ) a preform molding module that forms the shape of; an injection module connected to the preform molding module to supply resin material to the preform molding module; a container molding module including a container mold that injects air into the preform completed in the preform molding module to expand the preform to form the shape of the container; It includes a rotation table on which a lip plate on which the preform or container is mounted while rotating between the preform molding module and the container molding module, wherein the preform or container is placed upside down on the lip plate and is positioned on the top of the lip plate. By being supported to be disposed in an extended form, the lip plate is disposed below the preform or container, the inlet of the preform or container disposed on the lip plate is disposed to look downward, and the upper part of the rotary table The lip plate is detachably seated and supported, and the lip plate is moved by the operation of the preform molding module or the container molding module with respect to the rotary table during the work stage process by the preform molding module or the container molding module. A container manufacturing apparatus that can be removed from the rotary table and move up or down or remain seated on the rotary table has been disclosed.

The prior art of FIG. 1 includes a preform molding module that forms the shape of a pre-form of a container using a resin material; a container molding module including a container mold that injects air into the preform completed in the preform molding module to expand the preform to form the shape of the container; It includes a rotation table on which a lip plate on which the preform or container is mounted while rotating between the preform molding module and the container molding module, and is provided adjacent to the container molding module to form a cavity corresponding to the shape of the container. It is characterized by further including a label supply module that supplies labels before preform expansion inside the mold.

That is, in the prior art of Figure 1, the container is formed by forming a container preform and blow molding the container by injecting air while stretching the preform, but a label supply module that supplies the label before the preform expands inside the mold where the cavity is formed is used to supply the label. It is being formed.

This prior art consists of preforming the container in a blow molding machine → label forming → blow molding → unloading the molded container. When replacing the blow molding mold or preform mold, it must be replaced manually, which delays work time and increases safety. There are problems with the risk of accidents and low productivity.

In particular, recently, the Serious Accident Punishment Act has been newly established, and if a safety accident occurs at an industrial site, the CEO of the company will be subject to legal punishment. As the risk of safety accidents is very high when replacing heavy blow molds, an alternative to solve this problem is required.

Republic of Korea Patent Publication No. 10-1585152

The present invention is intended to solve the above problems, and when manufacturing a container made of synthetic resin or PET material by blow, it is possible to automatically proceed from the preform of the container to the blow molding, and at the same time, it is possible to produce a container of a larger or smaller size than the container being molded. In order to mold a product, the mold being used must be replaced. Therefore, when replacing the blow mold (mold), a mold suitable for the container specifications can be automatically replaced to prevent safety accidents and speed up work to increase production efficiency. The purpose and

In addition, artificial intelligence (AI) helps reduce labor costs, prevent safety accidents, and improve productivity and quality by managing blow molded products through a PC or mobile device so that products can be molded using an automated system from basic preform injection molding to container blow molding. The purpose is to provide an automated blow molding system for containers with AI).

The present invention, as a means to achieve the above object, includes a preform injection unit for injecting a preform using PET raw material resin;

a preform delivery robot that moves the preform injected from the preform injection unit along a delivery guide rail while being placed on a delivery jig;

a preform alignment unit that waits and arranges a plurality of preforms moved by the preform delivery robot;

a blow molding mold unit that moves the plurality of preforms waiting in the preform alignment unit to a blow machine and blow molds them into the shape of a container;

a container carrying unit that cools the container formed in the blow molding mold unit and then transports the container into a packaging box;

a rotary exchange mold unit installed on one side of the container delivery unit and sequentially rotating a plurality of replacement molds and transferring them to a mold transfer lift;

It is characterized by an automated blow molding system for containers including a gantry loader that horizontally moves the mold transfer lift that lifts the replacement mold of the rotary exchange mold portion and guides the blow molding mold portion so that the mold can be exchanged.

The preform delivery robot is characterized by combining a delivery jig in which a plurality of preforms molded in the preform injection unit are combined and then supplying the preform to the preform alignment unit along the delivery guide rail.

The rotary exchange mold part is characterized in that it is provided with a rotating member sequentially rotated by a driving unit installed at the bottom, and an exchange mold disposed radially on the rotating member.

The gantry loader is installed to be connected to the top of a first support installed on one side of the rotary exchange mold part and a second support formed on one side of the blow molding part, and a mold transfer grift is installed to be guided by the gantry loader and move back and forth. The mold transfer lift is characterized in that a mold jig robot is installed at the bottom of the lift boom to move the exchange mold from the rotary exchange mold section to the blow molding mode section.

The process of forming containers made of synthetic resin containers, PVC containers, PET, etc. by the blow molding automation system of the present invention is,

After the PET raw material in the hopper is melted in the preform injection unit according to a signal from an automatic control device, injection molding a preform, which is the basic product of the container, using a preform mold;

A step of removing the preform injected from the preform injection unit from the preform mold and cooling it with an air cooler while it is inserted into the discharging jig at the bottom of the preform discharging robot;

Elevating the preform delivery robot connected to the delivery jig in which the preform is inserted and transferring it to the preform alignment unit along the delivery guide rail;

Transferring and preheating the preform transferred to the preform alignment unit along a guide rail and then seating it at the mold entrance of the blow molding mold unit;

forming a container by blowing while stretching the preform seated in the blow molding mold;

Transferring the molded container to a packaging box prepared in the container discharging unit through a container discharging and transporting device;

Holding and lifting the exchange mold of the rotary exchange mold part installed on one side of the container carrying unit with a mold transfer lift;

The mold transfer lift pulled up by holding the replacement mold is characterized by the step of exchanging the used mold of the blow molding mold portion by transporting it along a gantry loader.

The present invention is intended to provide an automated system for blow molding of containers that automatically performs everything from preform injection to blow molding using an automatic control device, and at the same time allows easy replacement of the mold of the blow molding mold portion.

The present invention provides an automation system with artificial intelligence (AI) so that when blow molding a container made of synthetic resin or PET material, from preform injection of the container to blow molding of the finished container product, it is provided with an automation system and a mold part for rotary exchange. By allowing the pre-installed mold in the blow molding part to be easily replaced with a prepared exchange mold, there is an effect of increasing productivity and reducing labor costs during the blow molding manufacturing process of the container, resulting in economic benefits.

Figure 1 is a perspective view showing a conventional container blow molding device.
Figure 2 is a plan view showing the container blow molding system of the present invention.
Figure 3 is a front view showing the container blow molding system of the present invention.
Figure 4 is a plan view showing the preform alignment part, blow molding mold part, and rotary exchange mold part according to the container blow molding system of the present invention.
Figure 5 is a side view showing the container blow molding system of the present invention.
Figure 6 is a cross-sectional illustration showing the container blow molding mold of the present invention.
Figure 7 is a front excerpt showing the blow molding mold portion of the container blow molding system of the present invention.
Figure 8 is a side view showing the blow molding mold portion of the container blow molding system of the present invention.
Figure 9 is a cross-sectional view of the injection mold combined state showing the state in which the preform is molded by the preform injection mold in the preform injection unit of the present invention.
Figure 10 is an example diagram showing a state in which a preform injected from the preform injection unit of the present invention is separated from the injection mold.
Figure 11 is a blow molding system diagram showing a state in which the blow molding of a container is operated as an automated system by an automatic control device according to the present invention.
Figure 12 is an automatic control device that controls the blow molding of the container according to the present invention to be operated by an automated system.

Hereinafter, embodiments of the present invention will be described in detail based on the accompanying drawings.

Figure 2 is a plan view showing the container blow molding system of the present invention, which includes a preform injection unit 10 that molds the preform 1 by melting the raw material and then injecting it from an injection mold into a molded body, and the preform injection unit 10 A preform discharging robot 13 for transporting the preform 1, a preform aligning unit 20 for receiving and supplying the preform injected from the preform discharging robot 13, and a preform sorting unit 20 for receiving and supplying the preform injected from the preform discharging robot 13. A blow molding mold part 30 for blow molding, a container discharging part 40 for discharging the container molded from the blow molding mold part 30, and a blow molding mold part installed on one side of the container discharging part 40. It consists of a rotary exchange mold part (50) that can replace the forming mold (31) of (30).

Since the preform injection unit 10 shown in FIG. 2 of the present invention is not intended for use, specific drawings will be omitted and only the preform mold (FIG. 9) will be shown for explanation.

The preform injection unit 10 of the present invention is composed of a first mold part 80 and a second mold part 90, as shown in Figures 9 and 10, and the first mold part 80 has a guide pin ( Guided by 81), the preform 1 is molded while coming into close contact with and separating from the second mold part 90.

The molded preform (1) is separated from the second mold unit (90), is coupled to the delivery jig (11), and is then transferred to the preform alignment unit (20) by the preform delivery robot (13).

The first mold part 80 includes a core fixing plate 82 having a plurality of cores, an eject plate 85 into which a preform core 83 and a fixing ring 84 are inserted and retracted, and the eject plate 85 and an oil seal plate (86) installed between the neck ring plate (86), a pair of neck ring plates (87), a neck ring (87-1) and a slide block (88) installed on the neck ring plate (87). ), and a handle block (89) installed in the space of the slide block (88).

In addition, the second mold part 90 supports a plurality of cavities 93 for injection molding the preform 1 by forming a preform molding resin hole 92 when the preform core 91 is combined, and the cavity 93. cavity base 94, a preform gate insert 95 located at the bottom of each cavity 94 and injecting resin, and a handle gate insert 97 that injects resin into the handle molding resin hole 96 of the handle block 89. ).

After the preform (1) is injection molded as described above, the first mold part (80) and the second mold part (90) are opened and separated, and the preform delivery robot (13) descends and advances to the position of the preform (1). When this happens, the vacuum is opened and the preform (1) is discharged to the discharging jig (11) provided at the bottom of the preform discharging robot (13) by the mold opening and closing cylinder (97).

In this way, the preform (1) injected from the preform injection unit (10) is guided and transported to the delivery guide rail (12) by the preform delivery robot (13) while being inserted into the delivery jig (11).

The preform delivery robot 13 guides the delivery jig 11, into which the plurality of preforms 1 molded in the preform injection unit 10, are inserted, to the delivery guide rail 12 and transfers the preform 1 to the preform alignment unit 20. ) is supplied.

The take-out guide rail 12 is connected between the preform injection unit 10 and the preform alignment unit 20, and the preform take-out robot 13 reciprocates along the take-out guide rail 12.

The electrical device and electronic control device configured to reciprocate on the take-out guide rail (12) while the preform take-out robot (13) is coupled to the take-out jig (11) is a technology commonly used in automation equipment in industrial sites. In the invention, detailed description is omitted.

Figure 3 is a front view showing the container blow molding system according to the present invention, Figure 4 is a plan view showing the preform alignment part, blow molding mold part, and rotary exchange mold part according to the container blow molding system of the present invention, and Figure 5 is a plan view showing the container blow molding system according to the present invention. This is a side view showing the container blow molding system of the invention.

The preform alignment unit 20 is a blow molding mold portion on one side after loading the delivery jig 11 in which a plurality of preforms 1 are combined by the preform delivery robot 13 moving along the delivery guide rail 12. It is arranged so that it can be supplied sequentially to (30).

The preform (1) is molded in the preform injection unit (10), and then 3-6 preforms are coupled to the delivery jig (11), and the delivery jig (11) is connected to the preform delivery robot (13). The preform (1) is loaded into the preform alignment unit (20), is separated from the delivery jig (11), moves to one side, enters a standby state, and is again transferred to the preform injection unit (10) by the preform delivery robot (13). ), the operation of loading the unloading jig 11 is repeated, so that the preform 1 is in a waiting state in the preform alignment unit 20.

The plurality of preforms (1) waiting in the preform alignment unit (20) are moved to the blow machine (21) and sequentially supplied to the blow molding mold unit (30) for blow molding into the shape of a container.

The preform coupled to the inlet of the blow molding mold part 30 is stretched and blown by air pressure to form a container, and the molded container is transported to the container unloading unit 40 by the container unloading and transfer device 33 and boxed. is packaged by

This invention is an automated system with artificial intelligence (AI) that simplifies the container manufacturing process and improves productivity by manufacturing the container in a single system from preform injection to blow molding when blow molding the container. ..

In particular, the present invention integrates the container blow molding process into a single system using the automatic control device 100, so that the preform 1 can be remotely controlled in one process from injection to blow molding, rather than having to manufacture the preform through a separately installed injection machine or by requesting an outsourcing company. and automated processing, there are economic advantages in terms of product productivity improvement, quality control, logistics costs, and labor costs.

In addition, the present invention uses an automatic control device with artificial intelligence (AI) to systematize the blow molding process of the container and at the same time replaces the mold 31 of the blow mold 30 with the rotary exchange mold 50 when necessary. ) can be replaced with the exchange mold (53) provided. The exchange mold 53 can be easily and easily replaced using the mold transfer lift 60 and gantry loader 70.

The rotary exchange mold part 50 is installed on one side of the container delivery part 40 and is configured to sequentially rotate a plurality of replacement molds 53 so that they can be lifted by the mold transfer lift 60.

The rotary exchange mold part 50 includes a rotating member 52 sequentially rotated by a driving part 51 installed at the bottom, and an exchange mold 53 radially disposed on the rotating member 52. It is provided.

The driving unit 51 installed at the lower part of the rotary exchange mold part 50 is driven by a motor installed on one side so as to be connected, and the rotating member 52 rotates sequentially to form a radially installed exchange mold 53. After being coupled to the mold jig robot 62 of the mold transfer lift 60, it is lifted and guided by the generator loader 70 so that it can be transferred to the blow molding mold unit 30.

The gantry loader 70 is installed to be connected to the top of the first support 71 installed on one side of the rotary exchange mold part 50 and the second support 72 installed on one side of the blow molding mold part 30, A mold transfer lift 60 is installed to be guided by the gantry loader 70 and move back and forth.

The mold transfer lift 60 has a mold jig robot 62 installed at the bottom of the lift boom 61 to move the mold 31 from the rotary exchange mold part 50 to the blow molding mode part 30. Let it happen.

When the exchange mold 53 of the rotary exchange mold part 50 is combined with the mold jig robot 62, the rotating member 52 rotates at a predetermined interval by the electric and electronic operation of the drive unit 51. The rotating motion stops when the lift boom 61 of the mold transfer lift 60 descends and the mold jig robot 62 combines the exchange mold 53, and the mold jig robot 62 When the exchange mold 53 is held and lifted, the drive unit 51 rotates again to sequentially move the exchange mold 53 on one side to a position where it is coupled to the mold jig robot 62.

The forming mold 31 mounted on the blow molding mold part 30 and the exchange molding mold 53 stored in the rotary exchange mold part 50 described in the present invention are identical molds with only differences in specifications. The mold of the used blow molding mold part 30 is referred to as the forming mold 31, and the preforming mold stored in the rotary exchange mold part 50 is referred to as the exchange forming mold 53.

Figure 5 is a side view showing the container blow molding system of the present invention, in which the exchange mold 53 of the rotary exchange mold part 50 is installed at the bottom of the mold transfer lift 60 with the mold jig robot 62. ), lift the lift boom 61, and then move the mold transfer lift 60 to one side on the gantry loader 70 and place it on the upper part of the blow molding mold part 30.

At this time, in a state where the mold transfer lift 60 is located at the upper part of the blow molding mold part 30 with the exchange mold 53 coupled, the used forming mold 31 of the blow molding mold part 30 is located at the upper part. The replacement mold 53, which is moved backward by the installed cylinder 35 and coupled to the mold jig robot 62 of the mold transfer lift 60 located at the top, is lowered and mounted, and the mold replacement is performed at the same time.

The mold clamp 34 used in the blow molding mold part 30 is connected to the upper part and the movable holder 36 connected to the rod of the cylinder 35, so that when the cylinder 35 is operated, it moves backwards. It is configured to break away.

In addition, the movable holder 36 is installed on the shaft 37 installed on the upper part of the blow molding mold 30 in the front and rear direction, and when the cylinder 35 is operated, the movable holder 36 is guided by the shaft 37 and moves back and forth. do.

Figure 6 is a cross-sectional view showing the container molding mold of the present invention, which is installed in the blow molding mold portion 30, where the preform (1) is coupled to the inlet neck portion and is blown to closely adhere to the inner wall of the molding mold (31) to form the shape of the container. is molded into

The forming mold 31 is configured to open and contract left and right, and a mold gate insert 32 is installed in the lower mold at the bottom.

Figure 7 is a front excerpt showing the blow molding portion of the container blow molding system of the present invention, and Figure 8 is a side view showing the blow molding mold portion of the container blow molding system of the present invention.

A cylinder 35 and a shaft 37 are installed on the upper part of the blow molding mold part 30 of the present invention to replace the mold 31 as described above, and are connected to the cylinder rod of the cylinder 35. The movable holder 36 is connected, and the movable holder 36 is connected to the mold clamp 34. When the cylinder 35 is operated, the cylinder rod pulls the movable holder 36 and the forming mold 31 moves backward. It is configured to break away.

In addition, the movable holder 36 is installed on the shaft 37 on the upper part of the blow molding mold 30 in the front and rear direction. When the cylinder 35 is operated, the movable holder 36 inserted into the shaft 37 pulls the cylinder rod. It is moved backwards on the shaft by force.

The forming mold 31 is capable of blow molding eight containers at a time by installing a plurality of molds in which four container-shaped molds are formed in one mold to the blow molding mold part 30.

Therefore, the present invention automates the blow molding of containers made of synthetic resin or PET material so that the container can be completed in one system from preform injection to blow molding of the finished product, and at the same time is provided with a rotary exchange mold part 50 to form a blow molding mold part ( By allowing the forming mold 31 of 30) to be easily replaced, economic benefits can be achieved by increasing productivity and reducing labor costs during the blow molding manufacturing process of the container.

Figure 9 is a cross-sectional view of the injection mold coupled state showing the state in which the preform is molded by the preform injection mold in the preform injection unit of the present invention, and Figure 10 is a state in which the preform injected from the preform injection unit of the present invention is separated from the injection mold. This is an example diagram showing.

9 and 10 show a preform molding resin hole ( 91) is formed, and in one handle mold, the convex part of the handle core corresponds to the handle molding resin hole 95 of the handle block 89, and then PET resin is inserted through the preform gate insert 94 and the handle gate insert 96. Inject to fill the preform molding resin hole (91) and the handle molding resin hole (95) with resin.

The first mold part 80 and the second mold part 90 of the present invention are closely coupled to form a preform molding resin hole 91 between the cavity 92 and the preform core 83 and the handle block 89 of the one-side handle mold. ), and after cooling, the preform (1) is demolded.

The core fixing plate 82 of the first mold part 80 has a plurality of preform cores 83 and a handle core 97 formed on the bottom of the cavity 92 and the handle block of the second mold part 90. When entering (89), a preform molding resin hole (91) and a handle molding resin hole (95) are formed.

Forming a plurality of preform cores 83 and handle cores 97 on the core fixing plate 82 of the first mold part 80 is to inject a large amount of PET bottle preforms at once.

In addition, a plurality of slide blocks 89 to which the neck ring 87-1 is coupled to the upper surface are installed on the neck ring plate 87, and the neck ring 87-1 is connected to the first mold portion 80 and the second mold. When the part 90 is coupled, it is installed to engage with the upper part of the cavity 92.

The neck ring (87-1) is inserted into and slides on the preform core (83) installed on the core fixing plate (82), and the neck ring (87-1) and slide block (89) on which the neck ring plate (87) is installed Multiple preforms are installed so that multiple preforms can be molded at once.

The preform molding resin hole 91 and the handle molding resin hole 95 are formed when the preform core 83 of the first mold part 80 is combined with the cavity 92 of the second mold part 90. ) and the cavity 92. A preform molded resin hole 91 is formed.

At this time, the handle core 97 formed on one side of the preform core 83 is inserted into the space of the slide block 88 and correspondingly coupled with the handle molding resin hole 95 of the handle block 89.

PET resin is injected into the preform molding resin hole 91 and the handle molding resin hole 95 formed in this way through the preform gate insert 94 and the handle gate insert 96 and cooled to form a preform with the handle integrally formed. At this time, in the handle forming the concave portion, the handle core 97 is first separated and spaced apart, and then the handle block 89 is opened, so that the handle is molded and demolded without deformation.

As described above, when injection is completed in the first mold part 80 and the second mold part 90 of the preform injection part 10, the first mold part 80 and the second mold part 90 are opened, and the preform The delivery robot 13 operates to descend and advance toward the preform mold, and at the same time, the vacuum is opened and released, and the preform is opened by the operation of the lower mold opening and closing cylinder 98 of the second mold part 90, as shown in FIG. 10. It is discharged and inserted into the take-out jig 11 provided at the bottom of the preform take-out robot 13, and the preform take-out robot 13 rises and is then guided by the take-out guide rail 12 and transferred to the preform alignment unit 20.

Figure 11 is a blow molding schematic diagram showing a state in which the blow molding of a container is operated as an automated system by an automatic control device according to the present invention, and Figure 12 is an automatic system that controls the blow molding of a container according to the present invention to be operated as an automated system. It is a control device.

The automatic container blow molding system of the present invention is implemented with artificial intelligence (AI) by an automatic control device (100). That is, the automatic control device 100 can be remotely controlled by a mobile device or computer (PC) through wireless Internet or wired Internet.

The automatic control device 100 includes a preform injection unit 10, a preform half-full robot 13, a preform alignment unit 20, a blow molding mold unit 30, a container discharge unit 40, and a rotary exchange mold unit ( 50), the mold transfer lift 60 can be sequentially and automatically controlled, and its operation signal is processed by the preset memory value of the automatic control device.

In addition, in controlling the automatic control system for the blow molding of the container using the automatic control device 100, it can be remotely controlled using a mobile device such as a mobile phone or a computer (PC), so that when manufacturing the container by blow, the worker must be You can drive while monitoring from outside without the need for management.

In other words, by giving the automatic control device 100 an artificial intelligence (AI) function, it is possible to break away from the existing manufacturing method and implement a new manufacturing method.

For reference, artificial intelligence (AI) is currently creating intelligent computers with an internal structure capable of parallel processing, with several integrated circuits containing millions of central processing units (CPUs), memories, and input/output devices contained within one small silicon chip. It refers to performing several independent operations such as memory, logic, control, etc. simultaneously.

Digital computers perform these operations serially or sequentially. That is, a separate input circuit stores data in each memory device, and one piece of information at a time is transmitted from this memory device to the central processing unit for processing, and the results are output to an external output device. The fastest computer ever developed can perform about 10 billion calculations per second, so in modern industrial society, artificial intelligence computers are being incorporated to improve product productivity, and unmanned and automated systems are being introduced without on-site work managers. As a matter of fact, the automatic container blow molding system of the present invention also connects the automatic control device 100 and a digital computer to implement a system applying artificial intelligence (AI) functions.

The present invention as described above has been described with reference to the drawings of preferred embodiments, but this is merely illustrative, and various modifications and other equivalent embodiments can be made by those skilled in the art. You will understand.

Therefore, the present invention is capable of various changes and modifications within the spirit and scope of the claims claimed as the subject matter of the patent, and it will be natural that simple design changes fall within the scope of the rights of the present invention.

1: Preform 10: Preform injection unit
11: Take-out jig 12: Take-out guide rail
13: Freeform delivery robot 20: Freeform alignment unit
21: Blow machine 30: Blow molding mold part
31: Molding mold 32: Mold gate insert
33: Container take-out and transfer device 34: Mold clamp
35: Cylinder 36: Mobile holder
37: Shaft 40: Container carrying unit
50: Mold part for rotary exchange 51: Driving part
52: Rotating member 53: Exchange tongue mold
60: Mold transfer lift 61: Lift boom
62: Mold jig robot 70: Gantry loader
71:1st pillar 72:2nd pillar
80: First mold 81: Guide bar
82: Core fixing plate 83: Freeform core
84: Fixing ring 85: Eject plate
86: Oil seal plate 87: Neck ring plate
87-1: Neck ring 88: Slide block
89: Handle block 90: Second mold part
91: Preform molded resin hole 92: Cavity
93: Cavity base 94: Freeform gate insert
95: Handle molded resin hole 96: Handle gate insert
97: Handle core 98: Mold opening and closing cylinder
100: Automatic control device

Claims (6)

A preform injection unit that injects preforms using plastic raw material resin;
a preform delivery robot that moves the preform injected from the preform injection unit along a delivery guide rail while being fixed to the delivery jig;
a preform alignment unit that aligns and cools a plurality of preforms moved by the preform delivery robot;
a blow molding mold unit that moves the plurality of preforms waiting in the preform alignment unit to a blow machine and blow molds them into the shape of a container;
a container carrying unit that cools the container formed in the blow molding mold unit and then transports the container into a packaging box;
a rotary exchange mold unit installed on one side of the container delivery unit and sequentially rotating a plurality of forming molds and transferring them to a mold transfer lift;
a gantry loader that horizontally moves a mold transfer lift that lifts the mold of the rotary exchange mold section to exchange the mold of the blow molding section;
An automated system for blow molding of containers, characterized in that it includes an automatic control device to control each of the driving units. According to paragraph 1,
The preform delivery robot is an automated blow molding system for containers, characterized in that it combines a delivery jig in which a plurality of preforms molded in the preform injection unit are combined and then supplies the preform to the preform alignment unit along the delivery guide rail. According to paragraph 1,
An automated system for blow molding of containers, characterized in that the rotary exchange mold part is provided with a rotating member sequentially rotated by a driving unit installed at the bottom, and an exchange mold disposed radially on the rotating member. According to paragraph 1,
The gantry loader is installed to be connected to the top of a first support installed on one side of the rotary exchange mold part and a second support formed on one side of the blow molding part, and a mold transfer lift is installed to be guided by the gantry loader and move back and forth. , The mold transfer lift is a container blow molding automation system, characterized in that a mold jig robot is installed at the bottom of the lift boom to move the mold from the rotary exchange mold section to the blow molding mode section. According to paragraph 1,
The automatic control device is connected to wireless or wired Internet and can be remotely controlled by mobile or computer. The blow molding process of the container is,
After the PET raw material in the hopper is melted in the preform injection unit according to a signal from an automatic control device, injection molding a preform, which is the basic product of the container, using a preform mold;
A step of removing the preform injected from the preform injection unit from the preform mold and cooling it with an air cooler while it is inserted into the discharging jig at the bottom of the preform discharging robot;
Elevating the preform delivery robot connected to the delivery jig in which the preform is inserted and transferring it to the preform alignment unit along the delivery guide rail;
Transferring and preheating the preform transferred to the preform alignment unit along a guide rail and then seating it at the mold entrance of the blow molding mold unit;
forming a container by blowing while stretching the preform seated in the blow molding mold;
Transferring the molded container to a packaging box prepared in the container discharging unit through a container discharging and transporting device;
Holding and lifting the exchange mold of the rotary exchange mold part installed on one side of the container carrying unit with a mold transfer lift;
A blow molding method for a container, characterized by the step of holding the replacement mold and transporting the raised mold transfer lift along a gantry loader to exchange the used mold of the blow molding mold portion.

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