The runner and gate system used in plastic battery mould is responsible for directing molten plastic from the nozzle of the molding machine into the cavity of the tool. The gate architecture and its location affects cycle times, tooling costs, lead times, the location of witness marks and many other potential defects that are commonplace for injection molded parts.
1. Battery box mould:The Importance of Gate Location
The location of a gate directly affects the quality of the finished battery box mould, so consider these general rules:
· The gate should be placed away from pins, cores and other internal obstructions. Otherwise this may cause weld marks as molten plastic flows around them and reforms on the other side
· Gates should be placed closest to thick walled areas to ensure complete packing
· Improper gate location can cause part distortion if the build volume of the entire part is filled unevenly
· Gates are areas of high stress. Try to locate gates away from locations on the finished part that will be affected by stress marks or the potential degrading of plastic that happens in these areas
· Gates need to be located in areas that will be easy to degate, either manually or automatically. Note that some plastics are susceptible to high sheer forces and therefore can only be degated manually
· Thin walled parts might need flow channels or additional gates to provide a sufficient volume of plastic in a minimum cycle time
2. Battery box mould:Gate Design Can Effect Part Quality
All gates force molten plastic under pressure into the cavity which accelerates and heats the plastic as it does so. This creates a variety of effects of the battery box, which may need a change to gate design strategy. The most common defects include:
If the gate is too small the resulting pressure drop through the gate will cause jetting, that is, spraying into the cavity rather than flowing smoothly. Jetting causes wavy distortions called “worming”. This may require a decrease in pressure, an enlargement of the gate or both.
High injection speed through the gate creates heat through friction. Too much heat at this point may cause the resin to decay by destroying molecular bonds.
However, slowing down the injection speed to avoid degradation may cause other defects such as poor mechanical strength at weak weld lines. And slower cycle times means fewer parts per hour, increasing processing costs.
It’s possible therefore to divide a given volume of resin over a number of separate gate openings. This helps to dissipate pressure and avoid overheating, but it also creates multiple flow fronts which may cause weld lines and gas traps where these fronts meet inside the cavity.