KR20210056235A - Injection Molding System Based On AI and Method for Generating Molding Condition of Injection Molding System - Google Patents

Abstract

An artificial intelligence-based injection molding system according to an aspect of the present invention can change molding conditions so that good products can be produced when defective products are produced due to disturbance during injection molding, and comprises: an injection molding machine (100) for injection-molding a product by injecting a molding material into a mold; an injection state data acquisition unit (710) for acquiring current injection state data including at least one of a viscosity profile and an injection pressure value of the molding material injected into the mold during injection molding of the product; a determination unit (720) for determining whether to maintain the molding quality by inputting the current injection state data into a molding quality maintenance model (735) learned from predetermined target injection state data; and a molding condition setting unit (730) for changing predetermined molding conditions so that the current injection state data follows the target injection state data, when it is determined by the determination unit (720) that the molding quality is not maintained.

Description

Injection Molding System Based On AI and Method for Generating Molding Condition of Injection Molding System

The present invention relates to an injection molding system, and more particularly, to the control of the injection molding system.

Injection molding is the most widely used manufacturing method in manufacturing plastic products. For example, in products such as TVs, mobile phones, PDAs, etc., various parts including covers and cases may be manufactured through injection molding.

In general, manufacturing of a product through injection molding is carried out through the following processes. First, a molding material to which pigments, stabilizers, plasticizers, fillers, and the like are added is put into a hopper to make it melt. Next, the molten molding material is injected into the mold and then cooled to solidify. Next, after extracting the solidified molding material from the mold, unnecessary parts are removed. Products having various types and sizes are manufactured through these processes.

An injection molding machine is used as an equipment for performing such injection molding. The injection molding machine includes an injection device for supplying a molding material in a molten state, and a clamping device for solidifying the molding material in a molten state through cooling.

In order to manufacture a product with an injection molding machine, various molding conditions such as temperature, speed, pressure, or time must be properly set to produce a product with excellent quality. However, even if injection molding is performed with appropriate molding conditions set, high quality products may not be produced due to disturbances such as changes in temperature/humidity or changes in properties of molding materials during injection molding.

Accordingly, in order to produce a product of uniform quality, it is necessary to change the molding conditions according to the surrounding environment or changes in the properties of the molding materials, but if the operator changes the molding conditions, the molding conditions differ depending on the operator even if the same disturbance occurs. Since it can be set, there is a problem that it is difficult to expect a uniform molding quality.

The present invention is to solve the above-described problems, and provides an artificial intelligence-based injection molding system capable of changing molding conditions so that good products can be produced when defective products are produced due to disturbance during product injection molding. Make it a technical task.

In addition, according to the present invention, it is an object of the present invention to provide an artificial intelligence-based injection molding system capable of setting molding conditions capable of maintaining excellent molding quality using a deep learning-based molding quality maintenance model.

An injection molding system based on artificial intelligence according to an aspect of the present invention for achieving the above object comprises: an injection molding machine 100 for injection molding a product by injecting a molding material into a mold; An injection state data acquisition unit 710 for acquiring current injection state data including at least one of a viscosity profile and an injection pressure value of the molding material injected into the mold during injection molding of the product; A determination unit 720 for inputting the current injection state data into the molding quality maintenance model 735 learned from predetermined target injection state data to determine whether to maintain the molding quality; And a molding condition setting unit 730 for changing a preset molding condition so that the current injection state data follows the target injection state data when it is determined by the determination unit 720 that the molding quality is not maintained. It is characterized.

In order to achieve the above object, a method for generating molding conditions of an artificial intelligence-based injection molding system according to another aspect of the present invention includes the molding that is injected into the mold when injection molding a product by injecting a molding material into a mold. Acquiring current injection state data including at least one of a viscosity profile of the material and an injection pressure value; Determine whether to maintain the molding quality by inputting the current injection state data into the molding quality maintenance model 735 learned with target injection state data including at least one of the measured target viscosity profile and target injection pressure value during injection molding of good products The step of doing; And if it is determined that the molding quality is not maintained, changing a predetermined molding condition so that the current injection state data follows the target injection state data.

According to the present invention, when defective products are produced due to disturbances during product injection molding, the molding condition generating device implemented by a deep learning-based neural network network can automatically change the molding conditions, thereby improving product quality. It works.

In addition, according to the present invention, since the changing of the molding conditions is automatically performed by the molding condition generating device, there is an effect that the molding conditions can be changed to the good quality conditions in a short time even if there is no skilled expert.

1 is a view showing an artificial intelligence-based injection molding system according to an embodiment of the present invention.
2 is a view showing the configuration of an injection molding machine according to an embodiment of the present invention.
3 is a view showing that the fixed mold and the moving mold are opened.
4 is a view showing that a fixed mold and a moving mold are molded and closed by a moving part.
5 is a view showing the configuration of a molding condition generating apparatus according to an embodiment of the present invention.
6 is a flowchart showing a method of generating a molding condition according to an embodiment of the present invention.
7 is a flowchart showing a method of changing molding conditions according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing an artificial intelligence-based injection molding system according to an embodiment of the present invention.

The artificial intelligence-based injection molding system (10, hereinafter referred to as'injection molding system') according to the present invention uses molding materials to produce products according to optimal molding conditions. To this end, as shown in FIG. 1, the injection molding system 10 includes an injection molding machine 100 and a molding condition generating device 200.

The injection molding machine 100 according to the present invention performs injection molding to manufacture a product.

2 is a view showing the configuration of an injection molding machine 100 according to an embodiment of the present invention. The injection molding machine 100 will be described in more detail with reference to FIGS. 1 and 2.

1 and 2, the injection molding machine 100 according to the present invention includes an injection device 102 and a clamping device 103.

The injection device 102 supplies the molded material in a molten state to the clamping device 103. The injection device 102 may include a barrel 121, an injection screw 122 disposed inside the barrel 121, and an injection drive unit 123 for driving the injection screw 122. The barrel 121 may be disposed parallel to the first axis direction (X axis direction). The first axial direction (X-axis direction) may be a direction parallel to a direction in which the injection device 102 and the clamping device 103 are spaced apart from each other. When the molding material is supplied into the barrel 121, the injection drive unit 123 rotates the injection screw 122 to move the molding material supplied into the barrel 121 in the first direction (FD arrow direction). I can. In this process, the molding material can be melted by friction and heating. The first direction (FD arrow direction) is a direction from the injection device 102 toward the clamping device 103 and may be a direction parallel to the first axial direction (X-axis direction). When the molten molding material is located in the first direction (FD arrow direction) with respect to the injection screw 122, the injection drive unit 123 can move the injection screw 122 in the first direction (FD arrow direction). . Accordingly, the molten molding material can be supplied from the barrel 121 to the clamping device 103.

The clamping device 103 solidifies the molten molding material through cooling. The clamping device 103 is a fixed mold plate 131 to which the fixed mold 150 is coupled, a moving mold plate 132 to which the moving mold 160 is coupled, and the moving mold plate 132 in the first axis direction (X-axis direction). It may include a moving unit 133 to move along.

3 and 4 are views showing that a moving part molds and closes a fixed mold and a moving mold.

When the moving part 133 moves the moving platen 132 in the second direction (the direction of the SD arrow) to mold-close the moving mold 160 and the fixed mold 150, the injection device 102 A molten molding material is supplied into the fixed mold 150. The second direction (SD arrow direction) is a direction parallel to the first axis direction (X axis direction) and opposite to the first direction (FD arrow direction). After that, when the clamping device 103 solidifies the molten molding material filled in the moving mold 160 and the fixed mold 150 through cooling, the moving part 133 moves the moving mold plate 132 in the first direction. By moving in the direction of the FD arrow, the moving mold 160 and the fixed mold 150 are opened.

The clamping device 103 may include a tie bar 134. The tie bar 134 guides the movement of the moving platen 132. The movable platen 132 may be movably coupled to the tie bar 134. The moving platen 132 may move along the tie bar 134 in the first axis direction (X axis direction). The tie bar 134 may be disposed parallel to the first axis direction (X axis direction). The tie bar 134 may be coupled to be inserted into each of the fixed plate 131 and the movable plate 132.

On the other hand, the injection molding machine 100 according to the present invention produces a product by supplying the molding material to the molded moving mold 160 and the fixed mold 150 according to the molding conditions generated by the molding condition generating device 200. . Hereinafter, the moving mold 160 and the fixed mold 150 will be described as molds.

The molding condition generating device 200 generates a molding condition and transmits it to the injection molding machine 100. In addition, when the injection molding machine 100 is producing a product according to the created molding condition, the molding condition generating device 200 determines whether the molding quality is maintained, and the molding quality is not maintained due to disturbance. If it is determined that the molding conditions are changed.

Hereinafter, a molding condition generating apparatus 200 according to the present invention will be described in more detail with reference to FIG. 5.

5 is a view showing the configuration of a molding condition generating apparatus according to an embodiment of the present invention. As shown in FIG. 5, the molding condition generating apparatus 700 includes an injection state data acquisition unit 710, a determination unit 720, a molding condition setting unit 730, and a molding quality maintenance model 735. In FIG. 5, the determination unit 720, the molding condition setting unit 730, and the molding quality maintenance model 735 are shown as separate configurations, but this is only an example, the determination unit 720 and the molding condition setting unit ( The 730 may be implemented as one engine 725 configured in a software form. In addition, the molding condition generating apparatus 700 according to the present invention may further include a model generating unit 740 and a database 750 as shown in FIG. 5.

The injection state data acquisition unit 710 acquires injection state data from the injection molding machine 100 when the injection molding machine 100 is injection-molding a product. In one embodiment, the injection state data may include at least one of a viscosity profile and an injection pressure value of a molding material injected into the mold. At this time, the viscosity profile of the molding material may be calculated based on the thickness of the injection product and the amount of pressure change according to the change of time inside the mold.

For example, the injection state data acquisition unit 710 may calculate the viscosity profile of the molding material using Equation 1 below.

In Equation 1, η represents the viscosity (Visocity), σ _w represents the shear stress (Wall Shear Stress), and γ _w represents the shear rate (Wall Shear Rate). In addition, H represents the thickness of the injection product, L represents the flow distance defined as the distance between the pressure sensor and the temperature sensor (or the distance between two pressure sensors), △P represents the amount of pressure change, and △t represents the amount of time change. Represents. Here, the amount of pressure change means the amount of pressure changed during the flow by the flow distance (L), and the time change amount means the time taken during the flow by the flow distance (L).

To this end, the injection state data acquisition unit 710 may measure the amount of change in pressure inside the mold according to the amount of time change or measure the injection pressure when the injection operation by the injection molding machine 100 is in progress. The injection state data acquisition unit 710 calculates the viscosity profile of the molding material using the measured time change amount, pressure change amount, thickness of the injection product, and flow distance.

The injection state data acquisition unit 710 acquires the injection molding data from the injection molding machine 100 and provides it to the determination unit 720 at each predetermined time point or whenever an injection state data acquisition request is received from the determination unit 720. I can. Hereinafter, the injection state data acquired at each predetermined time point or whenever a request for obtaining injection state data is received will be referred to as current injection state data.

Meanwhile, when the product produced in the past by the injection molding machine 100 was a good product that satisfies a predetermined condition, the injection state data acquisition unit 710 uses the injection state data obtained during injection molding of the product as a target injection state data. And may store the determined target injection state data in the database 750. The target injection state data may include at least one of a target viscosity profile and a target injection pressure value, and the target viscosity profile is the amount of time change measured during injection molding of the product when the produced product is a good product that satisfies a predetermined condition. , Pressure change, thickness of the injection product, and flow distance can be calculated.

The determination unit 720 determines whether the quality of the product is maintained equal to the quality of the injected product according to a predetermined molding condition, using the current injection state data acquired by the data acquisition unit 710. In this case, the predetermined molding condition may be an initial molding condition that was set during the initial operation of the injection molding machine 100 by the molding condition setting unit 730, and such an initial molding condition may be a molding condition obtained during the production of good products.

In one embodiment, the determination unit 720 may determine whether the molding quality is maintained by inputting the current injection state data obtained by the injection state data acquisition unit 710 into the molding quality maintenance model 735. have. At this time, the molding quality maintenance model 720 may be a deep learning-based neural network that is learned from the target injection state data, and the molding quality maintenance model 735 includes the input current injection state data. If it is determined that it deviates from the threshold range set based on the data, it may be determined that the molding quality is not maintained.

The molding condition setting unit 730 sets an initial molding condition to be applied during the initial operation of the injection molding machine 100 and outputs it to the injection molding machine 100. In one embodiment, the initial molding condition may include at least one of temperature and pressure inside the mold, injection pressure, barrel temperature, injection speed, holding time, and holding pressure. In this case, the initial molding conditions may be set to the molding conditions obtained during the production of good products as described above.

In particular, the molding condition setting unit 730 according to the present invention may change the molding conditions applied to the injection molding machine 100 according to the determination result of whether to maintain the molding quality by the determination unit 720. When it is determined by the determination unit 720 that the molding quality is being maintained, the molding condition setting unit 730 determines that the currently set molding conditions are maintained. However, if the molding condition setting unit 730 determines that the molding quality is not being maintained by the determination unit 720, the current injection state data obtained by the injection state data acquisition unit 710 is the target injection state data. Change the molding conditions to follow

In an embodiment, the molding condition setting unit 730 may change at least one of an injection speed, a barrel temperature, and a mold temperature among molding conditions. The molding condition setting unit 730 may first change a molding condition that can be applied easily and quickly among injection speed, barrel temperature, and mold temperature. For example, since the injection speed is a molding condition that can be changed immediately, the molding condition setting unit 730 may determine that the injection speed is changed first. Although the barrel temperature can be controlled, since the application takes longer than the injection speed, the molding condition setting unit 730 may determine that the barrel temperature is changed after the injection speed is changed. In addition, the mold temperature can be controlled, but since it is not a direct configuration of the injection molding machine 100, the application time is relatively long, so the molding condition setting unit 730 changes the mold temperature after the change of the barrel temperature. You can decide.

Specifically, when it is determined that the molding quality is not maintained by the determination unit 720, the molding condition setting unit 730 uses the molding quality maintenance model 735 to determine the current injection state data and the target injection state data. The deviation is calculated and the injection speed is changed by a value proportional to the deviation so that the current injection state data follows the target injection state data.

For example, when it is determined that the molding quality is not maintained by the determination unit 720, the molding condition setting unit 730 uses the molding quality maintenance model 735 to determine the difference between the current viscosity profile and the target viscosity profile. After calculating, the injection speed is changed by a value proportional to the deviation so that the current viscosity profile follows the target viscosity profile.

At this time, if the viscosity profile value is large, it means that the viscosity is high, indicating that the molding material does not flow well, so if the current viscosity profile is larger than the target viscosity profile, increase the injection speed or increase the barrel temperature or mold temperature. It can be lowered so that the molding material flows well.

As another example, when it is determined that the molding quality is not maintained by the determination unit 720, the molding condition setting unit 730 uses the molding quality maintenance model 735 to use the current injection pressure value and the target injection pressure value. After calculating the deviation of between, the injection speed is changed by a value proportional to the deviation so that the current injection pressure value follows the target injection pressure value.

Here, when changing the injection speed to a value proportional to the deviation, the molding condition setting unit 730 changes the injection speed within a predetermined injection speed limit value.

When the injection speed is changed by a value proportional to the deviation, the molding condition setting unit 730 uses the molding quality maintenance model 735 to set the current injection state data to the target injection state. In order to follow the data, the injection speed is changed to the injection speed limit value, and the barrel temperature is changed by a value proportional to the deviation.

For example, when it is determined that the molding quality is not maintained by the determination unit 720, the molding condition setting unit 730 uses the molding quality maintenance model 735 to determine the difference between the current viscosity profile and the target viscosity profile. And, so that the current viscosity profile follows the target viscosity profile, the injection speed is changed to the injection speed limit value, and the barrel temperature is changed by a value proportional to the deviation.

As another example, when it is determined that the molding quality is not maintained by the determination unit 720, the molding condition setting unit 730 uses the molding quality maintenance model 735 to use the current injection pressure value and the target injection pressure value. Calculate the deviation of the gap, change the injection speed to the injection speed limit value so that the current injection pressure value follows the target injection pressure, and change the barrel temperature by a value proportional to the deviation.

Here, when changing the barrel temperature to a value proportional to the deviation, the molding condition setting unit 730 changes the barrel temperature within a predetermined barrel temperature limit value.

In this case, the molding condition setting unit 730 may change the barrel temperature by a value proportional to the remaining deviation excluding the deviation applied when the injection speed is changed to the injection speed limit value.

When the barrel temperature is changed by a value proportional to the deviation, the molding condition setting unit 730 uses the molding quality maintenance model 735 to set the current injection state data to the target injection state. To follow the data, the barrel temperature is changed to the barrel temperature limit value, and the mold temperature is changed by a value proportional to the deviation.

For example, when it is determined that the molding quality is not maintained by the determination unit 720, the molding condition setting unit 730 uses the molding quality maintenance model 735 to determine the difference between the current viscosity profile and the target viscosity profile. And, so that the current viscosity profile follows the target viscosity profile, the injection speed is changed to the injection speed limit value, the barrel temperature is changed to the barrel temperature limit value, and the mold temperature is changed by a value proportional to the deviation.

As another example, when it is determined that the molding quality is not maintained by the determination unit 720, the molding condition setting unit 730 uses the molding quality maintenance model 735 to use the current injection pressure value and the target injection pressure value. Calculate the deviation of the gap, change the injection speed to the injection speed limit value, change the barrel temperature to the barrel temperature limit value, and change the mold temperature by a value proportional to the deviation so that the current injection pressure value follows the target injection pressure. Let it.

Here, when the mold temperature is changed to a value proportional to the deviation, the molding condition setting unit 730 changes the mold temperature within a predetermined mold temperature limit value.

At this time, the molding condition setting unit 730, except for the deviation applied when the injection speed is changed to the injection speed limit value and the deviation applied when the barrel temperature is changed to the barrel temperature limit value, is a value proportional to the remaining deviation. You can also change the mold temperature.

When the mold temperature is changed by a value proportional to the deviation, the molding condition setting unit 730 changes the mold temperature to the mold temperature limit value when the mold temperature exceeds the mold temperature limit value.

On the other hand, if the mold temperature is changed by a value proportional to the deviation, if the mold temperature is out of the mold temperature limit value, the molding condition generating device 200 determines that it is difficult to maintain the molding quality and may generate an alarm to the operator. .

As described above, when there is a difference between the current injection state data and the target injection state data, the molding condition setting unit 730 according to the present invention includes the injection speed, the barrel temperature, and the mold so that the current injection state data follows the target injection state data. Since the temperature is sequentially changed, even if disturbance occurs during injection, the quality of the product produced through injection can be maintained at the same level as the good product.

In addition, according to the present invention, since the change of the molding conditions is not performed by the experience of the operator, but is performed using the molding quality maintenance model 735 composed of a deep learning-based neural network network, the molding regardless of the skill level of the operator The quality can be kept constant.

The molding condition setting unit 730 outputs the changed molding conditions to the injection molding machine 100. Accordingly, the injection molding machine 100 produces a product by performing injection molding according to the changed molding conditions.

When the current injection state data is input by the injection state data acquisition unit 710, the molding quality maintenance model 735 determines whether to maintain the molding quality based on the current injection state data and the target injection state data. The molding quality maintenance model 735 may be learned by the model generator 740. In one embodiment, the molding quality maintenance model 735 may be a deep learning-based neural network network that enables it to be determined whether or not to maintain the molding quality based on a plurality of weights and a plurality of biases. If this embodiment is followed, the molding quality maintenance model 735 may be implemented with an artificial neural network (ANN) algorithm.

The model generation unit 740 generates a molding quality maintenance model 735 and learns the generated molding quality maintenance model 735. Specifically, the model generation unit 740 may generate a molding quality maintenance model 735 by learning a neural network network using a plurality of target injection state data as a training data set.

Specifically, the model generation unit 740 generates a plurality of training data sets using at least one of a target viscosity profile and a target injection pressure value acquired during the production of good products, and trains a neural network network with the generated plurality of training data sets. By doing so, a molding quality maintenance model 735 is generated.

In addition, when the new target injection state data is generated at a certain period, the model generation unit 740 may learn the molding quality maintenance model 735 by using the new target injection state data.

As described above, the present invention determines whether or not to maintain the molding quality and changes the molding conditions for maintaining the molding quality through the molding quality maintenance model 735 generated by the model generation unit 740 by the operator without specialized knowledge about injection molding. As it can be guided to perform the injection process, the dependence of experts on the injection operation is reduced, and thus a smart factory in the injection field can be established based on an unmanned injection molding system.

The database 750 may store current injection state data and target injection state data generated by the injection state data acquisition unit 710. In addition, molding conditions set or changed by the molding condition setting unit 730 may be stored in the database 750. In addition, the database 750 may store various types of information used during injection molding.

Hereinafter, a method for generating molding conditions in the injection molding system according to the present invention will be described in detail with reference to FIG. 6. 6 is a flowchart showing a method of generating molding conditions in an injection molding system according to an embodiment of the present invention. The method of generating molding conditions in the injection molding system shown in FIG. 6 can be performed by the injection molding system shown in FIG. 1.

The injection molding machine 100 produces a product according to the molding conditions set by the molding condition generating device 200 (S800). In one embodiment, the injection molding machine may set a molding condition that was applied when a good product was being produced as an initial molding condition.

When the product is being injection-molded by the injection molding machine 100, the molding condition generating device 200 includes at least one of a current viscosity profile and a current injection pressure value of the molding material injected into the mold of the injection molding machine 100. The current injection state data is acquired (S810).

In one embodiment, the current viscosity profile may be calculated using the time change amount, the pressure change amount, the thickness of the injection product, and the flow distance during the injection molding of the product.

Thereafter, the molding condition generating apparatus 200 determines whether or not the molding quality is maintained based on the current injection molding data and the target injection molding data (S820). At this time, the target injection molding data refers to the injection state data that was acquired while producing good products. In one embodiment, the molding condition generating apparatus 200 may determine whether to maintain the molding quality by inputting the current injection state data to the molding quality maintenance model learned as the target injection state data.

Specifically, the molding condition generating device 200 determines that the molding quality is not maintained when it is determined that the current injection state data is out of the threshold range set based on the target injection state data by the molding quality maintenance model. If it is judged that it does not deviate from, it is judged that the molding quality is maintained.

As a result of the determination of S820, if it is determined that the molding quality is not maintained, the molding condition generating apparatus 200 changes the preset molding conditions so that the current injection state data follows the target injection state data (S830). In one embodiment, the molding condition generating apparatus 200 may change at least one of an injection speed, a barrel temperature, and a mold temperature among preset molding conditions.

At this time, as the molding conditions changed by the molding condition generating device 200 are output to the injection molding machine 100, the injection molding machine 100 performs injection molding according to the changed molding conditions (S800).

On the other hand, if it is determined that the molding quality is being maintained as a result of the determination in S820, the molding condition generating apparatus 200 determines that the currently applied molding condition is maintained (S840).

At this time, as the molding condition generating device 200 outputs that the molding condition is maintained, the injection molding machine 100 performs injection molding according to the applied molding condition (S800).

Hereinafter, a process in which the molding condition generating apparatus changes the molding conditions will be described in more detail with reference to FIG. 9. 9 is a flowchart showing a process of changing the molding condition by the molding condition generating apparatus according to an embodiment of the present invention. The process shown in FIG. 9 is performed by the molding condition generating apparatus 200, and the molding condition generating apparatus 200 may perform the process shown in FIG. 9 using a molding quality maintenance model.

First, when it is determined that the molding quality is not maintained as a result of the determination of S820 shown in FIG. 8, the molding condition generating apparatus 200 calculates a deviation between the current injection state data and the target injection state data (S900).

The molding condition generating device 200 changes the injection speed by a value proportional to the deviation (S910).

The molding condition generating device 200 determines whether the changed injection speed exceeds the injection speed limit value (S920).

As a result of the determination of S920, if it is determined that the changed injection speed does not exceed the injection speed limit value, the molding condition generating device 200 outputs the changed molding conditions including the changed injection speed to the injection molding machine 100 (S1000).

On the other hand, as a result of the determination of S920, if it is determined that the changed injection speed exceeds the injection speed limit value, the molding condition generating device 200 changes the injection speed to the injection speed limit value (S930), and the barrel temperature is proportional to the deviation. To change (S940). In this case, the barrel temperature may be changed as much as a value proportional to the remaining deviation, excluding the deviation applied when changing the injection speed to the injection speed limit value.

The molding condition generating device 200 determines whether the changed barrel temperature exceeds the barrel temperature limit value (S950).

As a result of the determination of S950, if it is determined that the changed barrel temperature does not exceed the barrel temperature limit value, the molding condition generating device 200 applies the changed molding conditions including the changed injection speed (injection speed limit value) and the changed barrel temperature to the injection molding machine 100. ) Is output (S1000).

On the other hand, as a result of the determination of S950, if it is determined that the changed barrel temperature is out of the barrel temperature limit value, the molding condition generating device 200 changes the barrel temperature to the barrel temperature limit value (S960), and the mold temperature by a value proportional to the deviation. To change (S970). In this case, the mold temperature may be changed by a value proportional to the remaining deviations excluding the deviation applied when the injection speed is changed to the injection speed limit value and the deviation applied when the barrel temperature is changed to the barrel temperature limit value.

The molding condition generating apparatus 200 determines whether the changed mold temperature exceeds the mold temperature limit value (S980).

As a result of the determination of S980, if it is determined that the changed mold temperature does not exceed the mold temperature limit value, the molding condition generating device 200 stores the changed injection speed (injection speed limit value), the changed barrel temperature (barrel temperature limit value), and the changed mold temperature. The changed molding conditions, including, are output to the injection molding machine 100 (S1000).

On the other hand, as a result of the determination of S950, when it is determined that the changed barrel temperature is outside the barrel temperature limit value, the molding condition generating device 200 changes the mold temperature to the mold temperature limit value (S990), and the changed injection speed (injection speed limit value), The changed molding conditions including the changed barrel temperature (barrel temperature limit value) and the changed mold temperature (mold temperature limit value) are output to the injection molding machine 100 (S1000).

On the other hand, when it is determined that the changed barrel temperature exceeds the barrel temperature limit value, the molding condition generating device 200 may determine that it is difficult to maintain the molding quality and may generate an alarm to the operator.

Those skilled in the art to which the present invention pertains will be able to understand that the above-described present invention can be implemented in other specific forms without changing the technical spirit or essential features thereof.

Therefore, it should be understood that the embodiments described above are illustrative in all respects and not limiting. The scope of the present invention is indicated by the claims to be described later rather than the detailed description, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts should be interpreted as being included in the scope of the present invention. do.

10: injection molding system 100: injection molding machine
200: molding condition generating device 710: injection state data acquisition unit
720: determination unit 730: molding condition setting unit
735: molding quality maintenance model 740: model generation unit
750: database

Claims (16)

An injection molding machine 100 for injection molding a product by injecting a molding material into a mold;
An injection state data acquisition unit 710 for acquiring current injection state data including at least one of a viscosity profile and an injection pressure value of the molding material injected into the mold during injection molding of the product;
A determination unit 720 that inputs the current injection state data into the molding quality maintenance model 735 learned from predetermined target injection state data to determine whether to maintain the molding quality; And
When it is determined that the molding quality is not maintained by the determination unit 720, the current injection state data comprises a molding condition setting unit 730 that changes a preset molding condition so that the target injection state data is followed. Injection molding system based on artificial intelligence. The method of claim 1,
The molding condition setting unit 730 changes at least one of an injection speed, a barrel temperature, and a mold temperature among the molding conditions. The method of claim 1,
The injection state data acquisition unit 710 acquires the viscosity profile using the thickness of the product to be injection-molded and the amount of pressure change according to a change in time inside the mold. The method of claim 1,
The target injection state data includes at least one of a target viscosity profile obtained during injection molding of a good product and a target injection pressure value measured during injection molding of the good product. The method of claim 1,
The determination unit 720 determines that the molding quality is not maintained when it is determined that the current injection state data is out of a threshold range set based on the target injection state data. The method of claim 1,
If it is determined that the molding quality is not maintained by the determination unit 720,
The molding condition setting unit 730 calculates a deviation between the current injection state data and the target injection state data, and injection within a predetermined injection speed limit value so that the current injection state data follows the target injection state data. Artificial intelligence-based injection molding system, characterized in that the speed is changed by a value proportional to the deviation. The method of claim 6,
When the injection speed is changed by a value proportional to the deviation, the molding condition setting unit 730 changes the injection speed to the injection speed limit value when the injection speed exceeds the injection speed limit value. Artificial intelligence-based injection molding system, characterized in that the barrel temperature is changed by a value proportional to the deviation within a predetermined barrel temperature limit value. The method of claim 7,
When the barrel temperature is changed by a value proportional to the deviation, the molding condition setting unit 730 changes the barrel temperature to the barrel temperature limit value, and in advance Artificial intelligence-based injection molding system, characterized in that the mold temperature is changed by a value proportional to the deviation within a predetermined mold temperature limit value. The method of claim 8,
When the mold temperature is changed by a value proportional to the deviation, the molding condition setting unit 730 changes the mold temperature to the mold temperature limit value when the mold temperature exceeds the mold temperature limit value. Injection molding system based on artificial intelligence. The method of claim 1,
A model generation unit that generates the molding quality maintenance model 735 by learning a neural network network with the target injection state data including at least one of a plurality of target viscosity profiles and a plurality of target injection pressure values measured during injection molding of good products Artificial intelligence-based injection molding system, characterized in that it further comprises (740). Acquiring current injection state data including at least one of a viscosity profile and an injection pressure value of the molding material injected into the mold when injection molding a product by injecting a molding material into a mold;
Determine whether to maintain the molding quality by inputting the current injection state data into the molding quality maintenance model 735 learned with target injection state data including at least one of the measured target viscosity profile and target injection pressure value during injection molding of good products The step of doing; And
If it is determined that the molding quality is not maintained, the method for generating molding conditions of an artificial intelligence-based injection molding system, comprising the step of changing a preset molding condition so that the current injection state data follows the target injection state data. . The method of claim 11,
The step of changing the molding conditions,
A method for generating molding conditions of an artificial intelligence-based injection molding system, characterized in that changing at least one of an injection speed, a barrel temperature, and a mold temperature among the molding conditions. The method of claim 11,
The step of changing the molding conditions,
If it is determined that the molding quality is not maintained, calculating a deviation between the current injection state data and the target injection state data, and changing the injection speed by a value proportional to the deviation within a predetermined injection speed limit value. A method for generating molding conditions of an artificial intelligence-based injection molding system, comprising: The method of claim 13,
The step of changing the molding conditions,
When the injection speed is changed by a value proportional to the deviation, when the injection speed exceeds the injection speed limit value, the injection speed is changed to the injection speed limit value, and the barrel temperature is set within a predetermined barrel temperature limit value. The method of generating molding conditions of an artificial intelligence-based injection molding system, further comprising the step of changing by a value proportional to the deviation. The method of claim 14,
The step of changing the molding conditions,
When the barrel temperature is changed by a value proportional to the deviation, when the barrel temperature is out of the barrel temperature limit value, the barrel temperature is changed to the barrel temperature limit value, and the mold temperature is set within a predetermined mold temperature limit value. The method of generating molding conditions of an artificial intelligence-based injection molding system, further comprising the step of changing by a value proportional to the deviation. The method of claim 15,
The step of changing the molding conditions,
When the mold temperature is changed by a value proportional to the deviation, when the mold temperature exceeds the mold temperature limit value, changing the mold temperature to the mold temperature limit value. How to create molding conditions for an injection molding system.

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