Summary of solutions for bubbles in the injection molding process

The solution to the bubble phenomenon in the injection molding process is as follows:
1. According to the cause of the bubble, the solution has the following aspects:
(1) When the wall thickness of the product is large, the outer surface is cooled faster than the center portion. Therefore, as the cooling progresses, the resin at the center portion is expanded toward the surface while being shrunk, so that the center portion is insufficiently filled. This condition is called a vacuum bubble. The main solutions are:
a) Determine the proper gate and runner size based on wall thickness. Generally, the height of the gate should be 50% to 60% of the wall thickness of the product.
b) A certain amount of supplementary injection material is left until the gate is sealed.
c) The injection time should be slightly longer than the gate sealing time.
d) reduce the injection speed and increase the injection pressure,
e) Use a material with a high melt viscosity rating.
(2) Due to the generation of bubbles caused by the generation of volatile gases, the main solutions are:
a) Adequate pre-drying.
b) Lower the temperature of the resin to avoid decomposition gases.
(3) Bubbles caused by poor fluidity can be solved by increasing the temperature of the resin and the mold and increasing the injection speed.
2. According to the cause of the bubble, the solution has the following aspects:
(1) When the wall thickness of the product is large, the outer surface is cooled faster than the center portion. Therefore, as the cooling progresses, the resin at the center portion is expanded toward the surface while being shrunk, so that the center portion is insufficiently filled. This condition is called a vacuum bubble. The main solutions are:
a) Determine the proper gate and runner size based on wall thickness. Generally, the height of the gate should be 50% to 60% of the wall thickness of the product.
b) A certain amount of supplementary injection material is left until the gate is sealed.
c) The injection time should be slightly longer than the gate sealing time.
d) reduce the injection speed and increase the injection pressure,
e) Use a material with a high melt viscosity rating.
(2) Due to the generation of bubbles caused by the generation of volatile gases, the main solutions are:
a) Adequate pre-drying.
b) Lower the temperature of the resin to avoid decomposition gases.
(3) Bubbles caused by poor fluidity can be solved by increasing the temperature of the resin and the mold and increasing the injection speed.
3. According to the cause of the bubble, the solution has the following aspects:
(1) When the wall thickness of the product is large, the outer surface is cooled faster than the center portion. Therefore, as the cooling progresses, the resin at the center portion is expanded toward the surface while being shrunk, so that the center portion is insufficiently filled. This condition is called a vacuum bubble. The main solutions are:
a) Determine the proper gate and runner size based on wall thickness. Generally, the height of the gate should be 50% to 60% of the wall thickness of the product.
b) A certain amount of supplementary injection material is left until the gate is sealed.
c) The injection time should be slightly longer than the gate sealing time.
d) reduce the injection speed and increase the injection pressure,
e) Use a material with a high melt viscosity rating.
(2) Due to the generation of bubbles caused by the generation of volatile gases, the main solutions are:
a) Adequate pre-drying.
b) Lower the temperature of the resin to avoid decomposition gases.
(3) Bubbles caused by poor fluidity can be solved by increasing the temperature of the resin and the mold and increasing the injection speed.

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