Chillers come in all sizes, from enormous, plant-sized central units that can deliver 500-plus tons of cooling per hour to plug-in portables that provide a single ton of capacity per hour.  So, how do you get the one that you need?

To size a chiller to meet your requirements, you’ve got to calculate the tonnage (chilling capacity) required to deliver the lowest required water temperature to your “process heat load.”  That’s the sum of heat that must be removed from 1) the molded or extruded plastic, and 2) heat sources in the process equipment, based on the influence of ambient conditions.

Choosing a Chiller Size

Basically, there are two ways to size a chiller.  The easiest way is to use sizing guidelines, developed by experts, which are shown below.

But, if you’re old-school, or you just like figuring things out yourself, part two of this blog explains the sizing process and equations, in detail.

The charts below are all you need.  These guidelines cover all of the heat-generating aspects of a typical injection molding or extrusion processes, including:

  • Material type and specific heat
  • Hydraulics, motors, and pumps
  • Heaters for barrels, molds, or hot runners
  • Temperature controllers
  • Dryer aftercoolers
  • Cooling tanks

These sizing guidelines have been validated over many years of processing experience, so they should provide a reliable estimate easily and safely. And, if you have questions, don’t hesitate to ask us.

Injection Molding Process Cooling Guidelines

Starting with materials, calculate the estimated heat loads for each factor associated with your process, then add up the results to obtain the estimated tonnage of cooling capacity required. 

  1. For each material type, divide the total pounds processed per hour by the number of pounds per hour that can be processed with one ton of cooling, per the chart.  For example, to injection mold PET at a rate of 300 pounds per hour, the material calculation is 300 / 45 = 6.67 tons of chilling capacity per hour.
  2. For hydraulic motors, add 0.1 ton of chiller capacity per motor hp.
  3. For feed throat, add 0.5 ton of chiller capacity.
  4. For Thermolator/Temperature control unit, add 0.2 ton of chiller capacity per motor hp.
  5. For dryer aftercooler (water-to-water only), consult manufacturer for required capacity, then add.
  6. For hot runners, add 0.15 ton of chilling capacity per kW of hot runner power consumption.

Extrusion Process Cooling Guidelines

Again, starting with materials, calculate the estimated heat loads for each factor of an extrusion process using the numbers provided in the extrusion chart, then add up the results to obtain the estimated chiller tonnage required.

  1. Materials
  2. Extruder Vacuum Pump
  3. Thermolator/Temperature control unit
  4. Extruder Gear Box
  5. Barrel
  6. Feed Throat
  7. Vacuum Cooling Tanks

Two other process variables:  Coolant mixes and flow rates

The lower portion of these charts display information about two other important variables in the operation of a chiller system:  the proportion of glycol and water needed for low-temperature coolant mixes (coolant used to deliver leaving water temperatures ≤ 40°F) and the flow rates of coolant (GPM) through common sizes of Schedule 40 steel and [Schedule 80] PVC piping.

A final note

Because your chiller is likely to see a range of heat loads and cooling temperatures, be sure to size it for the highest heat load and lowest temperatures you need it to handle. And, if you’re concerned about long-term operating costs, consider a chiller with a variable-speed compressor  for maximum energy efficiency in partial-load situations.

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How to Manually Calculate Chiller Capacity for Your Process

Learn more about the formulae you can use to calculate process heat load and chiller size.