KR20130134516A - Apparatus and method for analyzing mold deposit components in injection molding - Google Patents

Abstract

The present invention relates to an apparatus and a method for analyzing deposit components in a mold during an injection molding process, more specifically, to an apparatus and a method for extracting gas separated from a plastic resin deposited in a mold during the injection molding process and analyzing the elements and amount of gas. According to the present invention, deposition amount in a mold according to the cumulative number of injection molding and allows development of material with little deposition amount in a mold through comparison in deposition amount in a mold per plastic resins by grasping components that cause deposition in a mold.

Description

Apparatus and method for analyzing mold deposit components in injection molding}

The present invention relates to a sampling analysis apparatus for the mold deposition component in the injection molding process and an analysis method using the same. More specifically, the present invention relates to a method and apparatus for separating a gas component generated from a plastic resin deposited on a mold during injection molding to the outside from the mold surface and analyzing the component and amount thereof. The purpose of the present invention is to analyze the amount of deposition and to identify the cause of mold deposition, to provide a method for comparing the amount of mold deposition by plastic resin and developing a material having a low mold deposition amount.

Types of processing for making products from plastic resins include extrusion, injection molding, blow molding, calendering, and the like. In general, injection molding is a method in which thermoplastic plastics are processed by heating a plastic through an injection molding machine, melting it, pressing it into a mold mounted on the injection molding machine, and solidifying the molten resin, and then removing the molded product into a final product. One of the ways.

The plastic resin is melted in the barrel of the injection molding machine and then injected into the mold. Gas is present in the molten resin during the injection process, but the gas is generated by the resin, which is not sufficiently dried in the resin, air between pellets, and a monomer which is a low molecular material remaining in the resin after polymerization of the resin ( monomers and oligomers, gases from which low molecular weight materials or resins are excessively decomposed during plasticization, and gases generated from resins or low molecular weight materials that are thermally decomposed by shear frictional heat with a metal surface when resin is introduced into a mold. have.

Some of the gases are supplied to the low pressure injection machine hopper by back pressure during the plasticization of the injection process, but a large amount of gas remains in the molten plastic resin, and some of the gases present in the flow front are displaced to the mold surface. You will be calm. Most of the low molecular weight components are vented out through the gas vent of the mold or deposited on the mold surface and then vaporized into the air.

However, the high molecular weight multimer components cannot be discharged to the outside or vaporized and deposited on the mold surface. As the injection molding continues, the deposited components continue to accumulate on the mold surface. The deposited components cause defects in the appearance of the injection molded product, which may cause gas marks or poor gloss on the surface. In the case of injection molding fixing of plastic material in which mold deposition occurs, the mold is periodically cleaned to remove the components deposited on the mold, resulting in a loss of productivity and shortening the life of the mold.

The conventional method for analyzing the components deposited on the surface of the mold among the gases generated during injection molding is a method of removing the components on the surface of the mold and analyzing the components after several hundred consecutive injections. This method requires a significant number of injections to remove the deposited components from the mold.

In addition, a quantitative relative comparison of the amount deposited between plastic materials is not possible and it is not possible to measure the cumulative amount of the deposited component against the number of injections. Depending on the material, the amount of deposit on the mold is so small that it is not possible to remove the deposited components from the surface of the mold in the amount required for analysis.

Therefore, the present invention is the impurity deposited on the surface of the mold during plastic injection molding is the cause of appearance defects such as gas marks or poor gloss on the surface of the injection molded product. Dependent or randomly selected as a periodic mold cleaning cycle, the method provides a method for collecting the mold deposition components and analyzing the components and amounts thereof.

The present invention is to solve the above problems, as a method for collecting the component deposition component and component analysis, the metal rod (4) and the fixing jig (3) for obtaining the component deposited on the mold during the plastic injection molding process Characterized in that is formed.

On the other hand, as a method of collecting and analyzing the mold deposition components, using the above-described apparatus,

Depositing the metal rod and the fixing jig in the mold to obtain a component deposited in the mold before the injection molding process; And analyzing the components deposited on the metal rods; .

Hereinafter, the device provided by the present invention will be described in detail.

That is, in the present invention, the device for collecting and analyzing the components deposited on the mold during the injection molding is composed of a metal rod for obtaining the components deposited on the mold during the plastic injection molding process and a fixing jig for mounting the metal rod on the mold surface. It is characterized by the technical features.

In this case, the metal rod is preferably made of a metal material of the same material as the metal mold or a metal material commonly used in the metal mold making in terms of increasing the reliability of the analysis. The shape of the metal bar 4 is not limited thereto, but a relatively long cross section, such as a cylinder or a square, is advantageous for detaching and fixing the fixed side mold, and furthermore, considering the efficiency of deposition, the fixing jig 3 and It is more desirable to match the form.

In addition, the metal bar is preferably provided in the form of a removable metal bar and a fixed jig can be easily connected to the mold, and can be freely attached to the detached metal bar as needed.

Of these, the fixing jig serves to fix the obsolete metal rod to the mold surface. In addition, the position of the fixing jig 3 in the fixed side mold 2 is not specified as long as it can be externalized. For example, as described in the following examples, the fixed jig 3 can be externalized on the surface of the fixed side mold 2. have.

In addition, an analytical device used in the present invention is a GC-MS (Gas Chromatography-Mass Spectrometer), and serves to quantitatively and qualitatively analyze gas components deposited on metal bars.

Hereinafter, with reference to the accompanying drawings, the apparatus and the process of the present invention will be described in more detail.

Figure 1 schematically shows an example of the device connection configuration for the analysis of the mold deposition components that occur during injection molding according to the present invention, the analysis device is a moving side mold (1) and a fixed side mold (2) and a fixed jig ( 3) and a metal rod 4. At this time, the metal bar 4 is attached to the fixing jig 3 and is freely detachable as necessary.

The method of collecting and analyzing the components deposited on the mold during the double injection molding will be described in detail with reference to FIG.

First, the analysis method of the mold deposition component during injection molding is performed by using the apparatus of FIG. Connecting; Depositing a gas generated during injection molding on the metal rod 4 of the mold material; And detaching the metal rod 4 and analyzing the component and amount of the gas deposited on the metal rod 4 with a component analyzer such as GC-MS; ≪ / RTI >

During plastic injection molding, hot resin is filled in the molds 1 and 2, so that the gases generated are deposited on the metal rods 4. At this time, the gas deposition may be obtained by performing one injection molding, may be obtained by performing one or more injection moldings, or may be obtained by a fixed time operation.

In this case, it is also applicable to the moving side mold 1 of the plastic injection molding die, but since the ejection pin has a large number of ejection pins on the moving side of the mold, it is difficult to apply the metal rod and the jig to the fixed side mold 2. It is more preferable when considering ease.

Next, the component deposited on the metal rod 4 and its amount are measured by GC-MS.

The analysis may be continued by attaching a new metal bar at the time of desorption of the metal bar or at a later point in time.

When the component analysis on the metal rod mounted on the mold surface is completed during the injection process, the operator uses the component data to use it in post-process or new material development related process such as predicting the cleaning cycle of the mold. You can proceed. That is, the analysis data provided from the component analysis device may be utilized to preliminarily analyze the mold deposition amount of the material in the development of a material having a low mold deposition amount.

According to the present invention, it is possible to solve the problems that the analysis of the mold deposition component and application of the result during the injection process is difficult, and ultimately to collect and analyze the mold deposition component to utilize in the process to improve productivity, improve the life of the mold, develop new materials and It is effective in establishing optimized injection conditions.

1 is a block diagram of a main device for analyzing the deposition component of the gas generated during injection molding according to each embodiment of the present invention.
2 is a photograph taken with a digital camera a part of the surface of the mold after 500 times continuous injection molding according to the conventional method, it is observed that the gas marks on the surface of the mold.

Hereinafter, the present invention will be described in more detail with reference to Examples.

Example 1 Two kinds of ABS resin

As shown in FIG. 1, after mounting a rectangular metal rod 4 having a surface area of 360 mm ² with a NAK-80 material on a surface of a fixed side mold 2 having a NAK-80 material, general ABS (acrylonitrile butadiene styrene) ) The mold deposition component analysis on the metal rod was performed after 10 consecutive injections for the two resins. At this time, in the case of a material having a large amount of deposition, 1 to 20 times of continuous injection is preferable, and in the case of a material having a small amount of deposition, 20 to 100 times of continuous injection is preferable.

Sample 1 is T's general ABS, and there is a large amount of gas deposited on the surface of the mold during injection molding, so that the appearance defects such as the appearance of gas marks on the surface of the injection molded product and the gloss decrease are high. It is a material with a short mold cleaning cycle.

In addition, Sample 2 is a product name HF38X, which is a general product of LG Chem ABS, and has less deposition amount of gas on the mold surface and lower appearance defect rate than Sample 1.

For these ABS resin samples 1 and 2, the components and amounts deposited on the metal rods 4 in the gas generated during injection were analyzed by GC-MS and the results are shown as Table 1 below.

division Detection amount (μg) Sample 1 Sample 2 Component A 0.4 3.6 Component B 0.2 1.1 C component 5.4 0.0 D component 32.4 16.0 Other ingredients 1.8 1.2 Total amount 40.2 21.9

As shown in Table 1, the highest component deposition amount in both materials is the D component. Therefore, the direction of reducing component D in material development can be suggested to reduce defects due to mold deposition. In addition, it can be confirmed that the total amount of mold deposition components of Sample 2 is lower than that of Sample 1. Therefore, according to FIG. 1 of the present invention, the components deposited on the mold surface among the gases generated during the injection process are collected from the mold surface and analyzed to determine the degree of defects due to the deposition components before testing the actual product. It was.

Example 2 Two different ABS resins

The same experiment as in Example 1 was repeated, but instead of Sample 1, EF378L corresponding to LG Chemical Flame Retardant ABS was used as Sample 3, and instead of Sample 2, EF378L was replaced with an improved material of EF378L. The components and amounts deposited on the metal rod 4 by 20 consecutive injections were analyzed by GC-MS and the results are shown in Table 2 below.

For reference, Sample 3 has a high amount of deposit during injection molding, and thus has a high appearance defect rate such as poor gas marks on the surface of the injection molded product and poor gloss, and short mold cleaning cycle for removing gas on the mold surface. It is a material that needs improvement of its ingredients.

Sample 4 also corresponds to the material intended to minimize the H component suspected of mold deposition components in Table 2 below.

division Detection amount (μg) Sample 3 Sample 4 E component 2.2 2.2 F component 4.3 2.7 G component 1.3 1.1 H component 60.8 15.8 Other ingredients 3.2 2.5 Total amount 71.8 24.3

As shown in Table 2, since the highest component deposition amount of Sample 3 is the H component, it can be suggested that the material improvement to reduce the H component is required to reduce the appearance defects due to the mold deposition. As a result, Sample 4 having the reduced component H reduced the mold deposition component, and in actual product testing, it was confirmed that the appearance defects due to the mold deposition were lowered.

Comparative Example 1 Prior Art

The results of gas traces on the surface of the mold after 500 consecutive injection moldings according to the conventional method for the LUPOX HI-1002FA material, LG Chem's PBT series material, are shown in the photo in FIG. 2. Table 3 shows the components and amounts detected by analysis by GC-MS.

Detection components Detection amount (μg) I component 32 J component 137 K component 42 L component 24 Other ingredients 61 Total amount 296

As shown in Table 3, since the highest component deposition amount is the J component, it can be suggested that the material improvement is required to reduce the J component in order to reduce appearance defects due to the mold deposition.

However, in this method, a part of the gas component on the surface of the mold is buried in the swab and then the component can be analyzed on the swab, but it is impossible to accurately collect a certain part when collecting with the swab.

That is, according to the conventional method, it is difficult to obtain the same swab at the time of sample-by-sample comparison, and thus, quantitative comparative analysis of each sample is impossible.

In fact, as shown in the photograph of FIG. 2, in the conventional method, after 500 times of continuous injection molding, the gas traces on the surface of the mold were visually confirmed to confirm that there were many components on the mold. However, most of the materials are hardly visible when the surface of the mold is visually confirmed even after 500 consecutive injection molding, and it is difficult to show the difference between the samples by the visual observation method.

1. Moving side mold
2. Fixed side mold
3. Fixed jig
4. metal rod

Claims (11)

An apparatus for collecting mold deposition components and analyzing components, characterized in that the mold is provided with a metal rod 4 and a fixing jig 3 for obtaining the components deposited on the mold during the plastic injection molding process.
Harvesting analysis device for mold deposition components in the injection molding process.
The method of claim 1,
The metal rod (4) is characterized in that it is made of a mold material
Harvesting analysis device for mold deposition components in the injection molding process.
The method of claim 1,
The metal rod 4 is characterized in that it is embedded in the fixing jig (3)
Harvesting analysis device for mold deposition components in the injection molding process.
The method of claim 3,
The fixing jig 3 is characterized in that the obsolete metal rod 4 is mounted to be connected to the mold surface.
Harvesting analysis device for mold deposition components in the injection molding process.
The method of claim 1,
The metal rod (4) and the mold provided with the fixed jig (3) is characterized in that the fixed side mold (2)
Harvesting analysis device for mold deposition components in the injection molding process.
The method of claim 1,
Furthermore, a gas chromatography-mass spectrometer is used as the component analysis device.
Harvesting analysis device for mold deposition components in the injection molding process.
Use the device of claim 1,
Depositing the metal rod on the mold surface such that the metal rod is installed to obtain a component deposited in the mold during the injection molding process; And
Analyzing the components deposited on the metal rods; Characterized in that,
Extraction analysis method for mold deposition components in the injection molding process.
The method of claim 7, wherein
The collection analysis method,
Connecting a fixing jig in which a metal bar of a mold material is embedded on a surface of the mold of the fixed side of the plastic injection molding mold;
Depositing a gas generated during injection molding on a metal rod of a mold material; And
Analyzing the composition and amount of gas deposited on the metal rod by GC-MS; Characterized in that consists of
Extraction analysis method for mold deposition components in the injection molding process.
The method of claim 7, wherein
Analyzing the deposited component is characterized in that the step of removing the metal rod and then analyzing with a component analysis device
Extraction analysis method for mold deposition components in the injection molding process.
10. The method of claim 9,
When the metal bar is attached or detached after the new metal bar at a predetermined point of time characterized in that the analysis
Extraction analysis method for mold deposition components in the injection molding process.
10. The method of claim 9,
Analytical data provided from the component analysis device is characterized in that it is utilized during the preliminary analysis of the mold deposition amount of the material
Extraction analysis method for mold deposition components in the injection molding process.

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