When considering the secondary mold function, ie that of a heat exchanger it is not achieving uniform temperature across the injection mould which is important. The amount of heat energy absorbed by the mould varies dependent on the flow of material through the cavity. Around feed points there will be maximum heat generated due to material flow and shear. At the end of fill the material temperature will have reduced and the surface of the injection mold will absorb less heat energy.
Physical restrictions which restrict size of cooling channels such as small inserts, deep sections, etc have to be considered in each case. Also don't forget that whatever size your cooling channels, when you come to connect them to supply and return pipes you will have a reduction in area, due to the need to fit connectors.
There are many factors on which the diameter of the mold cooling channels depends, some are listed below:
- To cool the hotter section of the component in the mold. The cross section of the component has to be checked and the one with a greater area should be balanced or forcibly solidified
- To maintain injection mold temperature uniformity in the molding area.
- Sometimes hot oil circulation is also used to heat the mold to certain temperature or maintain the mold at a certain temperature.
- The type of plastic plays a very important role in deciding the diameter of the cooling channels.
- The mold design requirement is also a criterion (what is the quantity expected from a single mold).
Search Google for Injection Mold Design handbooks. Many have calculations for channel size. Size of channel also determines how close the channels should be to the part. Too large dia, too closely spaced, and too close and the mold steel will move under molding pressure. Pump G/Minute, number of circuits, diameter of channels, number of 90 degree bends in circuits, etc. All these need to be review for optimum water flow, pressure losses, heat removal etc.