A brief introduction to principles of mold flow analysis and how to read mold flow analysis reports
Time:2024-12-02 08:30:07 / Popularity: / Source:
Current mainstream mold flow analysis software is Moldflow, which only accepts triangular units and tetrahedral units.
High-quality finite element mesh is guarantee of finite element analysis accuracy.
For injection molded parts, there are three main mesh division methods in Moldflow: neutral surface, dual-face, and 3D entity.
| Part | Neutral surface | Dual-face | 3D entity |
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 |
 |
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| Division method | Extract neutral surface of part, then divide mesh (triangular unit) on neutral surface | Extract surface of part as core and cavity surface of mold, then divide mesh (triangular unit) | Directly divide finite element mesh on 3D digital model. |
| Advantages | Fewer meshes, fast analysis speed, and high calculation efficiency | No need to extract neutral surface, and post-processing is more realistic | High calculation accuracy |
| Disadvantages | Difficult to extract the neutral surface and low analysis accuracy | Meshes on upper and lower surfaces of part require a certain correspondence, and mesh division requirements are high | Large number of units, low calculation efficiency |
Applicable to thin-walled parts
Flow width is at least four times thickness
Use Hele-Shaw model for generalized Newtonian fluids
Follow Newtonian fluid mechanics
Ignore effects of inertia and gravity
Ignore heat conduction in the same plane
Ignore heat conduction through thickness
Ignore heat losses from edges
Starting from pouring point
Flow front grows to adjacent nodes
When one node is filled, another node is added
Material temperature enters model uniformly
Cooling of plastic depends on transferring heat to mold
For thick-walled and "short and fat" products
Aspect ratio less than 4:1
Use a true 3D solid model
Calculated at each node
Pressure
Temperature
Velocity in X, Y, and Z directions
Following items can be considered for heat conduction in all directions
·Inertia
·Gravity
Place gates to make flow
balanced
unidirectional
place gates
in thick wall areas
away from thin wall areas
towards mold wall to prevent ejection
prevent seam lines
in weaker areas of the product
appearance
prevent poor venting
add gates to
reduce filling pressure
prevent over-holding
gate placement depends on
mold type - two-plate mold or three-plate mold
runner - hot runner or cold runner
gate type - edge-in or submerged-in
mold design or functional requirements
for materials with long glass fibers, fiber orientation should also be considered
plastic material, flow capacity, filling capacity, product size, structural complexity, wall thickness and flow length ratio are comprehensively considered to determine type and approximate number of gates
Amorphous polymers
√Analysis of same structure during molding process
Crystalline polymers
√Compact structure when cooled, amorphous structure when heated
| Crystallinity | Non-crystalline | |
| Differences in physical properties | Opaque or translucent | Transparent |
| Chemical resistance | Good dimensional stability | |
| Large mold shrinkage | Low mold shrinkage | |
| Good solvent resistance | Good impact strength | |
| Easy to break under stress | Easy to break under stress | |
| Common types of plastics | PP | PS |
| HDPE | PMA | |
| LDPE | PC | |
| PA(Nylon) | MPPO | |
| POM | EVA | |
| PTFE | PSF | |
| PEO | PES | |
| PET | PEI | |
| PBT | PAI | |
| HIPS | PAR | |
For a good filling of product, its flow pattern is balanced. A balanced filling result: all processes end at the same time, and material flow front reaches end of model at the same time.
Contour lines in red box in above figure are dense, resulting in slight stagnation and slow flow. Because glue thickness is too thin, main wall thickness is 2mm and wall thickness in the middle area is 1mm.
Injection pressure>=80%*holding pressure.
Holding time should be greater than time for gate to cool 100%.
Influence:
Too low holding pressure may make part unable to be filled. Normally, holding pressure does not exceed 80Mpa. Too much pressure may cause batching. For thin-walled or complex products, holding pressure will be increased to maintain pressure smoothly, which may be greater than or equal to injection pressure.
If holding time is less than 100% cooling time of gate, part may be under-pressurized and surface defects may occur.
If holding pressure is still maintained after gate is 100% cooled. Holding pressure at this time will not have any effect on part, but will only waste labor time and increase costs.
Maximum clamping force should not exceed maximum clamping force of injection molding machine used to produce part.
Clamping force varies with injection pressure and holding pressure.
Effect:
If maximum clamping force exceeds maximum clamping force of injection molding machine used to produce part, flash may be generated on part.
Switch between injection and holding pressure should be between 95% and 99% of injection completion.
Pressure distribution should be as balanced as possible when switching to holding pressure
Pressure drop of gating system can be visually seen, which is helpful for optimizing gating system.
If injection volume is less than 95% of part volume, insufficient holding pressure may result. That is, some areas may have defects such as shrinkage and lack of material due to insufficient filling.
Unbalanced pressure distribution may cause inconsistent shrinkage of the part material, higher residual stress, and even insufficient or over-holding pressure in a certain area.
Change in temperature of melt front should be less than 20 degrees. Excessive temperature changes can cause residual stress inside part, and presence of residual stress can cause part to warp
As shown in figure, front temperature can be overlapped with weld line results to evaluate quality of weld line.
You can check gate freezing time. If holding time is less than gate 100% cooling time, it may cause insufficient holding of part and surface defects. If holding is continued after gate is 100% cooled. Holding at this time will not have any effect on part, but will only waste work time and increase costs.
You can check whether holding channel is smooth. The thicker area in circle in left figure above is frozen first, and effective holding is not obtained, which is more likely to shrink.
When product is 100% solidified and cold runner system is solidified by more than 50%, product can be demolded, thereby determining molding cycle of product.
Shear rate is an intermediate data result.
Maximum shear rate cannot exceed allowable value of material.
Impact:
If shear rate during injection exceeds maximum shear rate of material, material may degrade during injection process, resulting in many unexpected defects such as black spots, white spots, impact marks, etc.
Shear stress on wall is an intermediate data result.
Maximum shear stress on wall cannot exceed allowable value of material.
Impact:
If maximum shear stress inside part exceeds allowable value of material, product is prone to cracking and surface quality is poor.
Keep welds as short and few as possible.
Keep welds away from exterior and load-bearing structure.
Horizontal welds are better than vertical welds.
Evaluate welds together with weld temperature.
Venting grooves should be provided near weld line.
Weld lines can be eliminated or reduced by optimizing flow port position, product structure and wall thickness. Position of weld line can also be changed.
Impact:
Weld lines can cause surface defects.
Weld lines can reduce strength of part.
Air pockets should be distributed on boundary of part.
Venting grooves should be added to mold where air pockets exist.
Air pockets should be avoided on the surface of part.
Effects:
Air pockets may cause part to be underfilled, with bubbles on the surface and pores in part.
Air pockets may cause burning and cause scorching on part.
Target value of shrinkage rate of part is about 3 times shrinkage rate of mold. Generally, the thicker wall is and the farther it is from gate, the greater volume shrinkage rate. Shrinkage difference is the most common cause of deformation.
Volume shrinkage rate of each area cannot differ by 2%. If difference is too large, large warping deformation will occur. Further optimization of pressure holding is required to make volume shrinkage rate evenly distributed. If volume shrinkage rate of adjacent areas differs by 2%, surface area of product is prone to shrinkage. Volume shrinkage can be reduced by optimizing product wall thickness, placing gate in wall thickness area, and increasing pressure holding.
Note: Main factors affecting warpage of product should be caused by uneven shrinkage of material and glass fiber orientation, rather than insufficient cooling, molecular orientation and other factors.
For materials with long glass fibers, fiber orientation has a great influence on warpage deformation of product, which can be improved by optimizing gate position.
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