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Simulation Moldflow

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Simulation Moldflow

Installation and Licensing

Autodesk Simulation Moldflow Communicator Help

Visual Learning

Introduction to Autodesk Simulation Moldflow Communicator

Getting started

Molding processes

Analysis sequence

Materials and databases

Process settings

Results (Procedure)

Plot properties

Results Summary

Co-injection analysis results

Average temperature, cold runner result

Average temperature, part result

Circuit coolant temperature result

Circuit flow rate result

Circuit metal temperature result

Circuit Reynolds number result

Cool analysis log

Circuit heat flux

Circuit heat removal efficiency result

Circuit pressure result

Criteria for assessing cooling performance

Flow front temperature, mold-cavity result

Flux, part (top) result

Flux, part (bottom) result

Flux, part result

Frozen layer percentage, part (bottom) result

Frozen layer percentage, part (top) result

Maximum temperature position, part result

Mold-melt temperature difference (bottom), part result

Mold-melt temperature difference (top), part result

Mold-melt temperature difference result

Mold parting surface result

Percentage frozen layer, cold runner result

Percentage frozen layer result

Percentage molten layer result

Rapid heating and cooling circuit density result

Rapid heating and cooling circuit flow rate result

Rapid heating and cooling circuit pressure result

Rapid heating and cooling circuit Reynolds number result

Steam condensate mass result

Steam quality result

Temperature at surface, cold runner result

Temperature at surface, hot runner result

Temperature, circuit coolant (averaged) result

Temperature, circuit coolant (transient from start-up) result

Temperature, circuit coolant (transient) result

Temperature, core (averaged) result

Temperature, core (transient from start-up) result

Temperature, core (transient) result

Temperature difference, insert result

Temperature difference, part result

Temperature difference, parting plane result

Temperature, insert (bottom) result

Temperature, internal mold result

Temperature, parting plane (bottom) result

Temperature, insert (top) result

Temperature, maximum, cold runner

Temperature, maximum, part result

Temperature, mold boundary result

Temperature, mold (averaged) result

Temperature, mold (transient from start-up) result

Temperature, mold (transient) result

Temperature, mold-cavity interface (averaged) result

Temperature, mold-cavity interface (transient from start-up) result

Temperature, mold-cavity interface (transient) result

Temperature, mold-circuit interface (averaged) result

Temperature, mold-circuit interface (transient from start-up) result

Temperature, mold-circuit interface (transient) result

Temperature, mold-circuit interface (transient from start-up) result

Temperature, mold insert (averaged) result

Temperature, mold insert (transient from start-up) result

Temperature, mold insert (transient) result

Temperature, mold-insert difference (averaged) result

Temperature, mold-insert difference (transient from start-up) result

Temperature, mold-insert difference (transient) result

Temperature, mold-mold difference (averaged) result

Temperature, mold-mold difference (transient from start-up) result

Temperature, mold-mold difference (transient) result

Temperature, mold (top) result

Temperature, mold (bottom) result

Temperature, mold result

Temperature, mold (transient) result

Temperature, parting plane (top) result

Temperature, part (averaged) result

Temperature, part (transient from start-up) result

Temperature, part (transient) result

Temperature, part insert (averaged) result

Temperature, part insert (transient from start-up) result

Temperature, part insert (transient) result

Temperature, part result

Temperature, part (bottom) result

Temperature, part (top) result

Temperature, part insert result

Temperature profile, cold runner result

Temperature profile, hot runner result

Temperature profile, part result

Temperature, rapid heating and cooling thermocouples (transient) result

Temperature, rapid heating and cooling thermocouples (transient from start-up) result

Temperature residual, exterior shell result

Temperature residual, inserts result

Temperature residual, part result

Time to reach ejection temperature, cold runner result

Time to reach ejection temperature, part result

Cooling Quality analysis results

Fiber Orientation analysis results

Fill analysis results

Pack analysis results

Gas-assisted Fill+Pack analysis results

Gate Location analysis results

Design Adviser results

Injection-compression analysis results

Microcellular Injection Molding analysis results

Microchip Encapsulation analysis results

Molding Window analysis results

Optimization product results

Process Optimization analysis results

Reactive Molding analysis results

Runner Balance analysis results

Shrink analysis results

Sink Mark analysis results

Stress analysis results

Underfill Encapsulation analysis results

Warp analysis results

Birefringence analysis results

Reference materials

Troubleshooting guide

Glossary of Terms

Community Scoring

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Circuit Reynolds number result

Table of contents

1. Using this result
2. Things to look for

The Circuit Reynolds number result shows the Reynolds number of the coolant in the cooling circuit.

Using this result

When turbulent flow has been achieved, an increase in flow rate makes little difference to the rate of heat extraction; therefore, flow rate should only be set to achieve the ideal Reynolds number with minimum variations.

If you enter a minimum Reynolds number, use 10,000 as a minimum, and then check this result to ensure minimum variation. Do not aim for a Reynolds number that is greater than 10,000.

If you have parallel cooling channel circuits, it may be difficult to achieve minimum variation of the Reynolds number throughout all branches of the parallel circuit. If this is the case, consider changing the circuit layout. A Reynolds number below 4000 can be laminar and this will be less effective at removing heat from the cavity.

If there is a large variation in cooling channel diameter, there may be excessive variations in the Reynolds number. If this occurs, either adjust the cooling channel diameter, or reduce the minimum Reynolds number, ensuring the Reynolds number is always greater than 4000.

Things to look for

When viewing the Circuit Reynolds number result, watch for the following:

The Reynolds number should be greater than 4,000 for lines actively involved in cooling the part to ensure there is turbulent flow within the circuits and hence efficient cooling.
The ideal Reynolds number to achieve is 10,000.

NoteChanges such as those above, can only be made using a licensed Autodesk Simulation Moldflow Adviser or Autodesk Simulation Moldflow Insight product.

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