Today we discuss how to evaluate the stress concentration factor in a plastic part, actually in last blog, you can find a small illustration, please look at it carefully. there is a Mathematical relationship between radius and thickness for the stress concentration factor. it means when R/T values lesss than 0.5, the stress concentration factor is quite high, and when values of R/T over 0.5 the stress concentration factor gets lower. So at the inside radiuses of a plastic part, a minimum of 1 x thickness would be better.
Today’s product complexity, along with increasing downward pressure on overall pricing, has led to an inevitable increase in the geometric complexity of mechanical components. The increased geometric complexity allows components to be utilized in an advanced way, typically performing multiple functions. This multi-functional utilization has led to complex load transfers, resulting in new stress concentrations. the pressure to design components that can run for the longest number of cycles at the lowest price is significantly demanding.
A stress concentration is defined as high localized stress, compared to the average stress of the body, and is typically found in a region that has an abrupt geometric change or discontinuity. The body tends to fail at the location of a high-stress concentration or stress riser. This article will walk through the basics of stress concentration, offer real-world examples to illustrate the concept and outline methods for reducing stress concentrations in your designs.
Stress Concentration Factor
The effect of a stress riser can be determined quantitatively, utilizing mathematical methods such as the stress concentration factor. The stress concentration factor, Kt, can be defined as the ratio of the highest stress in the part to the reference stress, expressed as the following mathematical equation. Stress concentrations are relatively straightforward when it comes to identifying where they will be located and whether they have contributed to the failure. They will be located in the small radii and sharp corners that are in a load path.
The stress concentration factor is dependent on the geometry of the part. Components with more significant discontinuities in geometry will have higher stress concentration factors.
Stress Concentration-It’s All Geometry
Determining the location of stress concentrations and identifying whether they tend to cause failure is a relatively straightforward process. For example, there will be a stress concentration in geometric features such as small radii or sharp corners that are in a load path.
It’s important to note that the specify formula changes based on the load case and geometry, so further charts will need to be utilized for additional geometries. A good resource for finding curves for other geometries is “Stress Concentration Factors”. Now that we understand the basics, we can step into some examples of correcting stress concentrations.
By now, the idea of locating and mitigating the risk of stress concentrations should be clearly defined. While the FEA program was utilized here to determine the magnitude of stresses, the same general guidelines can be used to improve a design.
General Design Tips and Issues to Avoid
When it comes to common methods of reducing stress, the following list includes some simple guidelines to follow:
Make radii in a load path as large as possible.
Limit the ratio of the large feature to the small feature.
Add stress-reducing holes at the end of slits, sharp angles, or cracks to relieve high-stress concentrations.
Refer to stress concentration charts to understand when you are in a region of diminishing returns concerning radius size.
Some common issues to avoid are:
Do not use sharp corners along a load path.
Do not make a large-size transition between loaded features. The stiffness mismatch will drive the stress concentration much higher.
Don’t assume that the same size radius works for all features. Remember that the stress concentration is based on a ratio, not a magnitude.
Don’t place a stress concentration in a high cyclic load if you absolutely must use a sharp corner.
As you may have guessed, most of the “don’ts” are inverse to the “dos”. This list is not fully comprehensive, but it should cover the basic concepts and design tips that every designer should know to improve their design skills. Understanding the stress concentration effect on product or component longevity is important in areas like stress concentration in machine design.
Through the examples and analysis above, it should be clear exactly why we need to be concerned with stress concentrations. By incorporating these concepts through your design, you should be able to achieve higher load ratings, reliability, and fatigue life.
I encourage design teams to talk through product requirements and design tips and choices to ensure the proper blend of aesthetics and function while mitigating the effect of stress concentration. There will always be tradeoffs, but proper analysis can help achieve an optimized solution.
Stress Concentration FAQs:
Stress concentrations occur because of abrupt changes in geometry, such as a sharp radius or edge.
As the radius of curvature approaches zero, the stress concentration factor approaches infinity. Increase the radius of curvature to reduce the stress concentration factor.
The stress concentration factor is generally calculated by dividing the maximum stress by the average stress in a member, under loading.
A fillet provides lower stress concentration than a chamfer.
A stress concentration factor is a ratio of the maximum stress in a member to the average stress in a member.
If the maximum stress at the notch tip remains elastic its value can be obtained from the elastic stress concentration factor, a term that is very sensitive to notch radius. If this maximum stress becomes plastic, stress relaxation occurs and the elastoplastic stress concentration is less than the elastic one. However, the strain concentration factor is greater than kt. These three concentration factors are related in a relationship which depends of the level of the net section stress.
With the use of deformation theory, the stress-concentration factor at a circular hole in an infinite sheet of strain-hardening material subjected to equal biaxial tension at infinity is found for a variety of representative materials. The analysis exploits a transformation which permits the calculation of the stress-concentration factor without determining the stress distribution in the sheet. Subsequent calculations reveal that, for a monotonically increasing applied stress
Sharp internal corners and notches are perhaps the leading cause of failure of plastic parts. This is due to the abrupt rise in stress at sharp corners and is a function of the spe- cific geometry of the part and the sharpness of the corner or notch. The majority of plastics are notch sensitive and the increased stress at the notch, called the ‘‘Notch Effect’’, results in crack initiation. To assure that a specific part design is within safe stress limits, stress concentration factors can be computed for all corner areas. Formulas for specific shapes can be found in reference books on stress analysis.
thanks so much for sharing your experience on this issue
this blog is worth studying
thanks for sharing your experience
thanks for sharing your experience!
this is a good analysis method, thanks for sharing
you have good experience on this issue
your experience is worth learning
I must thank you for the efforts you have put in penning this site. I think many guys will get a lot of information they wanted from your blog
your experience on this issue is worth learning
you can write more about this issue, because it is very important.
Very nice experience, also your website design and layout are very good! I like it very much
thanks for sharing
stress concentration is very bad for an injection molding part
your experience on this issue is very useful, thanks for sharing
this blog is very useful for me
I think your experience on this issue is very helpful for our injection molding engineers
professional post. I got it, thanks!
your experience on this topic is very valuable
Good experience, nice website, definitely clean and awesome post.
thanks for sharing your experience
your analysis is very resonable, I learned something useful from it, thanks!
thank you for sharing your experience on this issue
thank you for sharing your exeperience, it is very good
your experience is very useful, I got it.
Thank you for sharing your expereince, it helps me a lot
you have done an outstanding job! your blog is very professional
thanks for sahring your experience
you studied this issue very well.
good experience! useful data
thanks for sharing your analysis data
good blog! it is very useful
you can have such conclusion, I believe that you are an expert
nice information, your blog is very professional,Thank you for sharing.
Wow! very professional analysis, you are a real expert
You seem to pay attention to summing up your experience and share with your colleagues
this Blog is very valuable, you convinced me
thanks for sharing your experience, it is very useful for me
thanks for sharing the experience like this, I need it
I’m so happy that I found your web site. You truly know what you’re talking
about, and you made me feel like I need to learn more about this.
I enjoy this web blog very much. A lot of terrific info.
Engaging post. I’ll return here for even more. Excellent site.
Fantastic post, I think webmasters should learn a lot
from this web blog its user-friendly and posts are
excellent.
Excellent post. Never knew this, appreciate it for letting
me know.
Thank you for sharing. I am impressed with your website.
I’ll post this to my facebook wall.
I’d constantly want to be updated on completely new content on this
web site, saved as a favorite!
Hi there, You’ve done an incredible job. I will certainly digg it and
personally recommend to my friends. I am sure they’ll be benefited
from this website.
Thank you for this excellent website. I am trying to read a lot
more articles. Thanks again!
Hi your question is a professional question, maybe professional guys can help you. our website also needs professional maintenance
Hi! Do you know if they make any plugins to safeguard against hackers?
I’m kinda paranoid about losing everything I’ve worked hard on. Any suggestions?
Good day! I was interested to know if setting up
a site such your own: //firstratemold.com/mirco-blog/how-to-evaluate-the-stress-concentration-factor-in-a-plastic-part/ is hard
to do for unskilled people? I’ve been hoping to set up my own website for
a while now but have been turned off mainly because I’ve always assumed it
demanded tons of work. What do you think? Thankyou
yes! you are right, but in our opinion, if you love something very much indeed! I think everything would be OK!
Wow! This might be one of the most helpful blogs we’ve ever arrive across about this subject.Excellent.
I’m also an expert in this topic therefore I can understand your effort.
It’s really a cool and helpful piece of information.
I’m satisfied that you shared this helpful info with us.
Please keep us up to date like this. Thanks for sharing.
Great post but I was wanting to know if you could write a litte more on this subject?
I’d be very grateful if you could elaborate a little bit further.
Cheers!
Thanks so much for sharing all of the great info!
I am looking forward to checking out more posts!
It’s actually a nice and helpful piece of info. I’m glad that you just shared this helpful info with us.
Please keep us informed. Thanks for sharing.