Liquid Cooling Guide
- Comala Publishing
This guide is provided as a reference for customers to simplify the selection process of appropriate cooling solutions for Flyway installations. Liquid cooling is optional, but recommended for demanding applications (e.g., operating at high power, achieving high precision movements, weighing payloads accurately).
Please see Flyway Cooling Setup for details on the installation.
Maximum Pressure
Flyway max permissible coolant pressure is 340 kPa (50 PSI).
Many commonly available 10mm tubing options are only rated to 275 kPa (40 PSI) or lower. Failure to observe pressure ratings of selected tubing may result in personal injury or damage to property caused by rupture and rapid decompression of coolant lines.
Flow Coefficient and Steady State Temperature
The Flyway flow factor, Kv, has been experimentally measured at approximately 0.42 m3/h for 3-Series and 0.44 m3/h for 4-Series.
An estimate of the system’s flow rate can be calculated using the pressure drop across the Flyways and the flow factor, Kv, for each Flyway as follows:
The following charts provide the projected flow rate through 3-Series and 4-Series Flyways connected in series for various pressure drop across the Flyway systems. These charts are only a projected flow rate, actual flow rate may vary depending on other components in line with your system and your specific pump’s capacity. For parallel cooling layouts, the projected flow rate can be estimated by multiplying the projected flowrate of each branch by the number of branches, assuming that each branch of the parallel layout contains the same number of Flyways.
The experimentally collected data in the graph below shows the measured steady-state temperature for different numbers of 3-Series Flyways in series with a small water chiller, with a least-squares best fit line applied. This data can provide a benchmark for system integrators when designing their cooling system. The chiller specifications and cooling liquid flowrate information is shown in the tables below. For the 16 Flyways in series and 8x2 Flyways in parallel test cases, the experimental chiller’s cooling capacity was saturated for power consumptions greater than 65 W per Flyway. If lower temperatures are required for the application parallel routing, increased liquid flowrates, and/or cooler input temperature should be implemented.
Experimental Conditions | |||
Water Chiller Data | |||
Nominal Cooling Capacity | 1700 W | ||
Pump Power | 48 W | ||
Compressor Power | 0.75 kW | ||
Maximum Flow | 16 L/min | ||
Ambient Temperature | 21 ⁰C | ||
Cooling Liquid | Distilled water | ||
Test Case | Liquid Flowrate [L/m] | Pressure Drop Across Flyways [kPa] | Liquid Input Temperature [°C] |
1 Flyway in Series | 5.0 | 74 | 18.5 |
2 Flyways in Series | 4.4 | 92 | 18.5 |
4 Flyways in Series | 3.7 | 112 | 18.6 |
8 Flyways in Series | 2.8 | 126 | 19.1 |
16 Flyways in Series | 2.1 | 147 | 19.5 |
2x8 Flyways in Parallel | 3.8 (Total) | 109 | 20.7 |
Condensation may occur on a cooled system if the system's surface temperature is below the dew point temperature of the air around the system. The dew point temperature depends on the humidity and ambient temperature and can be determined using the following chart. For example, for an ambient temperature of 20°C and a relative humidity of 70%, the dew point temperature is approximately, 14°C. The input temperature of the cooling liquid should therefore be set higher than 14°C to remove the chance of condensation. Integrators may also consider dehumidifying the ambient air to eliminate condensation.
Thermal Load Estimation
The thermal load of a system can be estimated using either of the following methods:
Compute from maximum rated capacity of system’s power supply(s)
The average power consumption of a Planar Motor system typically does not exceed half the rated power of the system’s AC/DC power supplies
Assume required cooling capacity is approximately equal to average power consumption
Compute from experimental results
Use the “Get Flyway Physical Status” function in Planar Motor Tool to obtain instantaneous Flyway power consumption of any given Flyway in the system
Record instantaneous power consumption of all Flyways during typical operation. Estimate required cooling capacity as equal to the cumulative instantaneous power consumption of all Flyways
For both methods, note that the chiller should have a maximum cooling capacity sufficiently above the actual thermal load of the system. If the thermal load approaches the chillers’ maximum capacity, an unacceptably high coolant temperature rise may occur. Choose a chiller with an oversized cooling capacity to avoid this problem.
Suitable Chillers for Common Applications
There are many chillers on the market which are suitable for cooling various sized Flyway systems. The table below contains examples of some chillers that are readily available. It is up to the customer to decide which chiller is suitable for their specific application:
Product | Cost [USD]* | Cooling Capacity [W] | Notes | Max Flyways** | Configuration |
|---|---|---|---|---|---|
~400 | 1400 | Accuracy ±1°C | 20 | 5 branches of 4 in series | |
~4000 | 1100 | Temperature stability 0.1°C | 20 | 5 branches of 4 in series | |
Request quote | 900 | Temperature stability 0.1°C | 16 | 4 branches of 4 in series | |
Request quote | 1100 | Accuracy ±2°C | 20 | 5 branches of 4 in series |
* Subject to change
** Max Flyway estimate is based on typical system loading of 50W per Flyway-mover pair, and chiller-specific considerations
Select a chiller based on analysis of cooling capacity, coolant temperature accuracy requirements, and budget.
Suitable Chiller Fluids for Common Applications
Flyway materials internally exposed to coolant include:
C3604 brass
6061 aluminum
304 stainless steel
Polymers
PBT
PP
POM
NBR
EuroTerm 131 is a recommended coolant solution because it prevents corrosion of the cooling system.
For small, or temporary installations, various fluids may be acceptable (e.g., ethylene glycol-based fluids, water, etc..).
Feedback and Comments
Please email us at tech.portal@planarmotor.com