It is also necessary to have mold sticking and demoulding abili

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    Because of the presence of surface defects in both the mold cavity and the flow channel, it is very easy for plastic parts to adhere to the injection molding process during the molding process. Because of the presence of surface defects in both the injection molding cavity and the flow channel, this results in difficult demoulding because the plastic parts adhere to the injection molding, making it difficult to remove them from the mold. It is important to remember that when polishing, the polishing tool's action direction should be the same as the direction in which melt is injected into the Injection Molding Company during the mold-making process.

     

    Following complete cooling, molten material that forms flash in the scratched part of a die or in the gap between the inserts will make deconstruction of the mold more difficult to complete. This situation necessitates repairing the damaged parts while also narrowing the gap between the inserts.

     

     

    As a result, when designing the mold, we must take care to ensure that it is rigid and strong enough to withstand repeated use. If the initial injection pressure used during the Injection Mold Making Services test exceeds a certain threshold, it is critical that the mold be rejected. Continue to increase the injection pressure incrementally while keeping an eye on the mold's deformation in order to maintain the mold's deformation within a specified range.

    All of these issues, as well as inadequate or moving demoulding slopes and a lack of parallelism between fixed formwork, can arise during the demoulding process.

    When designing and fabricating molds, it is important to consider the provision of a sufficient demoulding slope; otherwise, the removal of the plastic parts will be difficult.)As a result of the force used to force plastic parts out of the way, they are frequently warped, and the ejection parts are frequently white or cracked as is common in this situation. The moving and fixed templates on the mold should be placed in close proximity to one another; otherwise, the cavity will deviate and the demoulding will be substandard.

    The construction of the gate system is taking an unreasonably long time and is extremely complicated.

    Mold adhesion and demoulding will be poor when the sprue is too long and too small, the connecting part between the main sprue and sub sprue is not strong enough, the main sprue does not have a cold material cavity, the gate balance is poor, the main sprue diameter is not equal to the nozzle hole diameter, and the gate sleeve is not consistent with the spherical surface of the nozzle. To improve the strength of the connecting part between the main runner and shunt runner, it is recommended that a cold material cavity be installed on the main runner. Additionally, the length of the sprue should be appropriately reduced while its cross-sectional area should be increased.

    By increasing the position of the auxiliary gate, which is taken into consideration when determining gate position for a multi-cavity mold, it is possible to achieve a balance in the filling rates of each cavity while simultaneously decreasing the pressure in each cavity. It is recommended that the nozzle aperture be 0.5 to 1mm larger in diameter at the small end of the sprue, and that the concave radius of the gate sleeve be 1 to 2mm greater in radius than the nozzle's sphere radius, in accordance with the manufacturer's specifications.

    Inadequate stroke of the ejector, or unevenness in its operation, or poor performance of the top plate during the molding process result in the inability to demould the plastic components.

    To ensure a sufficient ejection stroke, it is recommended that, when conditions permit, the effective ejection area of the ejector rod be increased as much as possible when possible. For proper operation to be ensured, it is necessary to keep the ejection speed of plastic parts within a reasonable range, and not too fast or too slow. When the top plate moves poorly, the primary reason for this can be traced back to the viscosity that exists between the sliding components of the top plate itself.

    As a result, the gap between the column body and the sliding core becomes extremely small during continuous operation because there is no cooling device at the sliding core. A consequence of this phenomenon is that the pulling action of the core is frequently suboptimal, as the sliding core is typically hotter than the other cores in the system. For example, if there is a lack of parallelism between the top pin hole and the top plate guide pin, or if the top pin is bent, the top plate will behave in a less-than-satisfactory manner.

    When there is foreign matter between the top plate and the mounting plate, the top plate tilts as a result of the lack of a stop pin in the pressing mechanism.  If there is no stop pin set in the pushing mechanism, the top plate action will be poor. Poor action will result when only one ejector rod is in operation because the top plate of medium and large molds cannot move evenly when only one ejector rod is in operation.