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Infinity MFG
United States
Приєднався 4 бер 2014
Infinity MFG is an online learning program geared towards individuals that are either in or desire to be in the manufacturing industry such as engineering students, tradesmen, apprentices, or hobbyist. The primary goal is to address the STEM based skills gap that prevent people from entering or advancing in the manufacturing industry. Some secondary goals are to discuss industry trends, engineering skills, and new technologies that are shaping the industry in new and exciting ways.
The way to get the most out of this channel is to go to the playlist and look for the topic of interest. From there all of the videos are sorted by number and subject. I want this to be a quick reference and easy access.
The way to get the most out of this channel is to go to the playlist and look for the topic of interest. From there all of the videos are sorted by number and subject. I want this to be a quick reference and easy access.
Chain Rule Pactice Problems
Four practice problems for chain rule
Please pause the video and try the problem on your own first, then restart the video.
Facebook: infinitymfg/
Please pause the video and try the problem on your own first, then restart the video.
Facebook: infinitymfg/
Переглядів: 49
Відео
U Substitution Examples
Переглядів 559 годин тому
Four practice problems for u-substitution. Please pause the video and try the problem on your own first, then restart the video. Facebook: infinitymfg/
Gear Mechanics 4: Rotational Speed and Torque
Переглядів 12921 годину тому
This video shows the versatility of the velocity ratio and the various ways that it can be used to calculate several aspects of gear design, including diameters and torque. Facebook: infinitymfg/
Proving the Integrating Factor
Переглядів 72День тому
This video is to show how the integrating factor is derived and how it serves it's purpose of putting a first order linear equation into the form of the product rule. Facebook: infinitymfg/
Gear Mechanics 3: Velocity Ratio
Переглядів 133День тому
This is an example problem showing the applications of the velocity ratio equation and it also shows the versatility of the equation. Facebook: infinitymfg/
Product Rule and the Integrating Factor
Переглядів 72День тому
This video is to demonstrate how the integrating factor is used to put a first order linear differential equation into the form of the product rule. Facebook: infinitymfg/
Gear Analysis: Simple Gear System
Переглядів 27714 днів тому
This video is an example problem to show how to apply the gear ratio and how the center-to-center distance is calculated. Facebook: infinitymfg/
Gear Analysis: Velocity Ratio
Переглядів 10814 днів тому
This is a video that explains the velocity ratio (gear ratio) and shows the connection between gearing and the rotational analysis equation. Facebook: infinitymfg/
Rotational Analysis 8: Rotation of a Simple Disc
Переглядів 8621 день тому
A simple example of the rotation of a disk Facebook: infinitymfg/
Rotational Analysis 7: Gear Reduction of a Circular Saw
Переглядів 12321 день тому
Applying rotational analysis to a gear problem for a circular saw. Facebook: infinitymfg/
Rotational Analysis 6: Reduction Gear Box
Переглядів 12328 днів тому
Rotational analysis performed on a gear train Facebook: infinitymfg/
Rotational Analysis 5: Wind Turbine
Переглядів 123Місяць тому
This is another example problem for rotational analysis. In this problem there is a constant rotational analysis of a turbine blade in 2 different points. Facebook: infinitymfg/
Rotational Analysis of a simple gear train
Переглядів 144Місяць тому
Performing a rotational analysis of a simple gear train when the angular acceleration is given as a function of time. Facebook: infinitymfg/
Tangential versus Rotational Kinematics
Переглядів 190Місяць тому
This video discusses the relationship of the 4 kinematic equations, constant acceleration versus acceleration as a function and the method of deriving the velocity and displacement based on the acceleration. Facebook: infinitymfg/
Differential Equations (Part 9: Initial Value Problem Example)
Переглядів 494Рік тому
Differential Equations (Part 9: Initial Value Problem Example)
Mechanical Design (Part 11: Linkage Example 3)
Переглядів 1,5 тис.Рік тому
Mechanical Design (Part 11: Linkage Example 3)
Mechanical Design (Part 10: 4 Bar Linkage Example 2)
Переглядів 853Рік тому
Mechanical Design (Part 10: 4 Bar Linkage Example 2)
Mechanical Design (Part 9: 4 Bar Linkage Example)
Переглядів 2 тис.Рік тому
Mechanical Design (Part 9: 4 Bar Linkage Example)
Strength of Materials (Part 21: Axial Load, Support Reactions, Compatibility Conditions)
Переглядів 18 тис.3 роки тому
Strength of Materials (Part 21: Axial Load, Support Reactions, Compatibility Conditions)
Strength of Materials (Part 20: Axial Load and Relative Displacement)
Переглядів 4,2 тис.3 роки тому
Strength of Materials (Part 20: Axial Load and Relative Displacement)
Strength of Materials (Part 19: Axial Loads and Linear Deformation)
Переглядів 3,6 тис.3 роки тому
Strength of Materials (Part 19: Axial Loads and Linear Deformation)
Strength of Materials (Part 18: Calculating the normal strain)
Переглядів 3,9 тис.3 роки тому
Strength of Materials (Part 18: Calculating the normal strain)
Strength of Materials (Part 17: Example - Stress, Strain, Youngs Modulus)
Переглядів 2,7 тис.3 роки тому
Strength of Materials (Part 17: Example - Stress, Strain, Youngs Modulus)
Strength of Materials (Part 16: Static Equilibrium/Coordinate System)
Переглядів 1,4 тис.3 роки тому
Strength of Materials (Part 16: Static Equilibrium/Coordinate System)
Strength of Materials (Part 15: Developing a Free Body Diagram)
Переглядів 6 тис.3 роки тому
Strength of Materials (Part 15: Developing a Free Body Diagram)
Strength of Materials (Part 14: Support Reaction Test Problem)
Переглядів 1,7 тис.3 роки тому
Strength of Materials (Part 14: Support Reaction Test Problem)
Thanks… can you explain on manufacturing of Ferritic Stainless Steel from iron ore
I have an exam on kinematics tomorrow and you just made my life way easier! Thank you!
That's awesome! Good luck and thanks for watching!
Rotational speed (n) = 2700 rpm?
Ack! Typo! 😅
what a great overview of fundamentals of gears professor, thank you very much!
Thanks for watching!
Part 2? 3? 4? 5? 6?
5/4 rad would be sufficient for me. A little too complex for me. I'd have to sit down and look at the details. I guess that's why we're here.
Thank-you again for more excellent content.
Thank you too!
Thank-you for this content. Excellent!
Thank you sir
Thanks for watching!
Thanks for the video. Great revision on metallurgy. I did this as a qualification ten years ago. I still have all my books.
Thanks for watching. I appreciate your support.
Can a damaged or bent motor pulley cause vibration?
should the specimen has to be a defined shape and size?
Thanks so much for this three-part series. 30 years after college math, I ran into a practical situation with an ODE. You made it possible for me to both tackle and understand the problem.
Thanks1 That is really cool that this video was helpful to you.
Can i use little law to show inventory number between milling (station1) and welding (station 2) if i know the welding throughput rate and cycle time = inventory ?
Great video. THank you
Thanks! I really appreciated you taking the time to watch.
Informative video, and the sound - vin diesel (need for force) feel
Thanks for watching!
very nice. i like
Damp, damping. Not dampening , that’s to make wet.
Incorrect. It can actually mean both.
Thank you!
Thanks for watching!
Do you happen to know what water tanks is it made out of hot rolled or cold rolled and which one is it better to make it out of you know just for a simple water truck tank
Could you please recommend me best book for statistical quality control.
One other thing that minute 951 you said that putting the part on the three points eliminates the ability to go up and down it actually only illuminates the possibility of going down you can still go up, so could you explain that please
Hi Professor Cummings at minute seven you talk about the 321 rule and you have 3A, 3B, 3C. you seem to refer to them as three datum planes…when actually they are the same datum planes… so why would you call them ABC when they’re all co planer?
Thank you for this video
My pleasure. Thanks for watching.
Nice explained
Great Works!How do I pay to watch the previous class2~6? Thank you
dude, you're dope.
Thanks man!
I am trying to figure out if Hot forged tools vs. Cold forged tools are better. For example, socket wrenches: Gedore sockets are hot forged, they claim this is better than cold. Hazet sockets are cold forged. They claim theirs is better. (Hazet have a lot more money as a company and produce more consistent looking tools than Gedore, but are they stronger???). In the video you say hot rolled is stronger, but you also say cold rolled is stronger. So which is it? (I suppose this is like asking is Lafite '59 better than single malt whiskey). Obviously both methods work very very well because both of these German tool companies have thousands of users in Aerospace production and maintenance where money is not spared in hand tools (because a problem caused by cheap tools is infinitely more costly, so they actually spend more on tools to save money).
what a terrific course
thank so much sir, this really came handy. it is in this video that I have also understood the projections. Grateful
Thanks for your support!
works thankyou very much!
Thanks for watching.
You have turned the table around for keen learners with your highly expressive and organised presentation on the Part One video. I am looking forward to listening to the Second chapter on this. Thank you!
Why is there music playing in the background? It’s kind of distracting.
Great video... Not to critique the expert, but from what I've been reading, first angle is actually more common in Europe.. Third in the US...many thanks for the well laid out video!
You are explaining the process from the basic. It can be understandable for everyone
so far this actually the most inclusive about all the properties between the two types of steel that I've found so far. I have an interest since I'm a welder for a company producing flammable liquids containment solutions and deal strictly with coled rolled steel for its finish and strength over hot rolled
This solved my physics doubt of whats the difference between these two types of integration. Thanks
Thanks a lot for the tutorial which is very helpful to understand the difference between the two. What about cold drawn welded tubes? Is that the same process or part of it? anybody has a link to a tutorial for such process?
In the details you the blowup should be 2/1, not 1/2.
The right side view in the first angle projection... The inner-circle should be a hidden line.
Hello Professor Cummings. I am a training coordinator at a global manufacturing company and we are interested in using this video as an instructional tool in one of our internal training programs. Would you be able to grant permission to use the video?
Yes, feel free.
@@infinitymfg5397 Awesome! Thank you.
Doc, no matter how many tines I watch this same video, I continue to get value from it. Thank you sir, had you would have been my instructor back when I was undergraduate and graduate school I probably would have gotten my PHd.
Thanks. Comments like this are very motivational.
most people say things like the driver divided by the gear being driven , they dont say +x na/nb
This was helpful indeed: very often some "gurus" teach others math just for math purposes, without practical application and it kinda sucks
Mixing terms iron and carbon
P R O M O S M 🌹
this channel is *amazing!* much thanks.
Even after years, this video is still gold!
LOL! This is one of my first ones. I wanted to show to proof to my students.
Thats an impressive work done prof, please continue the good work. your tutorials have sharpened my understanding a lot thanks.
Thanks a lot Steven, I really appreciate it.