GD&T Tutorial 16 : Virtual Condition
ฝัง
- เผยแพร่เมื่อ 16 ต.ค. 2024
- GD&T Tutorial : Virtual Condition - This video explains about various boundary conditions like Worst Case Boundary, Inner Boundary, Outer Boundary, Virtual Condition in Geometric Dimensioning and Tolerancing (GD&T)
To download the presentation click the link below
we have removed the link due to miss use by viewers. Apologies for the inconvenience!
for more videos and professional courses on GD&T visit lms.prolotek.com
Worst Case Boundary is a general term used to refer to an inner boundary, outer boundary or virtual condition
For an internal FOS, inner boundary is the smallest FOS (MMC) minus the effect of applicable geometric tolerance and any additional tolerance that may apply
For an external FOS, inner boundary is the smallest FOS (LMC) minus the effect of applicable geometric tolerance and any additional tolerance that may apply
For an internal FOS, outer boundary is the largest FOS (LMC) plus the effect of applicable geometric tolerance and any additional tolerance that may apply
For an external FOS, outer boundary is the largest FOS (MMC) plus the effect of applicable geometric tolerance and any additional tolerance that may apply
Virtual Condition is a fixed size boundary generated by the collective effects of a considered FOS specified MMC or LMC and the geometric tolerance for that material condition
For IMMC : VC = IB = MMC - GTV
For ILMC : VC = OB = LMC + GTV
For IRFS : IB = MMC - GTV
For EMMC : VC = OB = MMC + GTV
For ELMC : VC = IB = LMC - GTV
For ERFS : OB = MMC + GTV
VC - Virtual Condition
RC - Resultant Condition
IB - Inner Boundary
OB - Outer Boundary
BT - Bonus Tolerance
GTV - Geometric Tol. Value
![ILLSLICK - WINTER IS COMING [Official Video]](http://i.ytimg.com/vi/dwTMeM1zIhQ/mqdefault.jpg)
![[UNCUT]"ทนายตั้ม" แฉยับ! ความลับสวรรค์ ใครคือ "บิ๊กเทวดา" ของบอสพอล l คนดังนั่งเคลียร์ l 15 ต.ค. 67](http://i.ytimg.com/vi/ru9fpSaUwdA/mqdefault.jpg)
very nicely explained!!! finally this gdt principle is getting in my head!!! 🙂
Kindly make videos on stackup as well. Gd&t is very important topic and most of the people don't share this knowledge. You are really changing lives. Please keep going... Many many thanks.
Sure I will
Virtual boundary calculated at MMC of Internal feature tells me the maximum shaft size that the hole can accommodate. Similarly what is the use of Virtual boundary calculated at LMC of Internal feature. Please clarify
It is difficult to put it in word how useful this video is for me...Good job sir...god bless you.
Thanks and welcome
What an explanation!!!!!
Thanks a lot sir for all the videos...
I would like to suggest please make a series on jig & fixturing design
Great suggestion!
Thank you so much sir...For uploading such a knowledgeable content...
I would like to request you to upload some videos regarding CAD Modeling (Creo), Design Considerations, Modeling Strategy, Domain Theory..
Thank you for this video. Was wondering why have separate boundary and virtual terms to describe the same thing! It's clear now. Not sure if you have made a video on applying material conditions to Datums and also stack up tolerances as requested by another reader. Will look out for them. Thankyou very much..
Please do videos on stack up analysis as well those will help us more.
will take some time please
How do we calculate/assign the tolerance +/- value for a shaft and hole?! For example for a 30mm shaft/hole how do we assign tolerance +/-value ?please explain this
sir Generally what do you mean by worst case because lot of confusion is their between virtual condition and resultant condition
HI Sir, can you please explain for virtual condition, LMC concept-external feature? oculd not understand how a hole of 29.4 dia will pass through the shaft in all conditions?
Sir please add videos on Tol. Stackup in depth
noted
Sir you said there is an inner boundary for internal and external feature. And also outer boundary for internal and external boundary.. But you explained examples for inner boundary of an internal structure and outer boundary of external structure..
Which means what about the other two sir.?
At 9:29 in video
For LMC hole you obtained VC = 30.6 , the LMC of the hole is 30.5
Kindly tell me how a geometric counter part (shaft) equal to 30.6 will mate with LMC hole of 30.5
Same doubt for LMC Of shaft.
Because in both cases the shaft is bigger than the hole size
Great explanation. i like it
Simplified concepts...well explained
Thank you
Any specific topic you require, please let me know
@@PalaniKailash sir, I want to learn on position tolerance inspection.
will post a video on it some time later
@@PalaniKailash thanks sir
Hi Palini Kailash excellent explication. I would like you help me to understand the effect of RFS, MMC and LMC.The differences of explanation of the surface method and axis method of ASME Y14.5-2018. thanks and I hope your best answer.
Check out my video RFS Vs MMC Vs LMC for explanation
Sir, kindly provide the presentation for this lecture.
Hello sir ...it means the ring gauges (Go, no-go) and plug gauges (Go, no-go) are designed by considering VC for internal & eternal feature of size ?
the assembly mating parts are designed based on the virtual conditions and helps for gauge design as well
QUESTION SIR
sir i tried from scratch
say size i am referring is 50 dia desired fit i have selected is H7- g6 to be yield
H7 = 50.000 AND 5.025 g6 = 49.091 and 49.075 is desired fit
recommended position tolerance for size 50 is 0.1
now started from hole as we follow hole basis system
say 50.000 as MMC INNER BOUNDARY VC comes out 49.9
now shaft i need to be dimensioned must be around 49.9 with OUTER BOUNDARY VC
but currently according to basic tolerance g6 = 49.091 and 49.075 ( 49.9 is fitting in this TZ)
PLEASE CONVEY CALCULATION
PLEASE MAKE VIDEO EXPLAINING FROM SCRATCH from NOMIAL SIZE TO GD AND T TILL FINAL FIT
QUESTION SIR
DIA 50 MM NOMIAL
ASSEMBLY fit H7 - g6 needed
position tolerance recomended 0.1
please convey calculation for VC INNER OR OUTER (HOW TO DECIDE ) BOUNDARIES
for ----LIMITS OF GIVEN DESIRED FIT
Good information sir...
Hello Sir , pdf download link is not working , can u please correct it ?
Why dia mention dia-29.5 left side exterm condition
Sir at 1:15 for both internal and external fos u mentioned as MMC
Hi Sir ,
Thanks for making such informative videos.
I have a question regarding the position tolerance calculation
Let's assume we have to fasten two flanges with m20 bolts.In one flange there is M20 tapping and 2nd has dia 22 clearance hole. The number of hole is 12 at equal spacing.. Orientation and pcd of hole is given the basic dimension ..
How to calculate the position tolerance value for both M20 tapping and dia 22 hole.
Thanks in advance..
I have explained this in this video
th-cam.com/video/HWtaxScGjWM/w-d-xo.html
@@PalaniKailash Thanks a lot..
Thank you
What is meant by wall thickness? Please clear this input.
from edge of a hole to edge of the adjustment surface is an example of wall thickness
Well explained
Good to hear
Very nice 👌
thankyou
Can you please make a video on datums having mmb
sure, in some time i will
Related AME and Boundaries are not the same thing...AME are only considered with physical part, and they can change from part to part...they don't exist unless you have a physical part...VC though can be calculated from the information on the drawing. So please be careful of these terms, maybe edit your video to edit that.
If VC is same as IB and OB , rhen why we r studying it .
VC can be either IB or OB depending upon MMC or LMC conditions.
VC is important for deciding the size tolerance to ensure assembly. Only when the VC of shaft and VC of hole is same, we will be able to assemble the parts considering the dimensional tolerance and geometric tolerance
@@PalaniKailash thanks a lot sir
@@PalaniKailash But in case of LMC(internal FOS), as per example in the video the VC of hole is 30.6mm which is not the worst case. Worst case would be 30.4mm (30.5-0.1). Then how a pin with VC of 30.6 can be assembled in 30.4mm hole (considering worst case) although the VC is same ?
Sir ...voice should have been louder
👌
👍