Fundamentals of GD&T-1.pdf
17,462 views
123 slides
Jun 07, 2022
Slide 1 of 123
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
About This Presentation
basic GD & T
Slide Content
AMT2506
1
M.S Ramaiah School of Advanced Studies - Bengaluru
K.N. Ganapathi
Asst Professor
Mechanical and Manufacturing Engineering
MSRSAS
Fundamentals of Geometric
Dimensioning and Tolerancing
(Basic GD&T)
Based on ASME Y14.5M
1
M.S Ramaiah School of Advanced Studies - Bengaluru
K.N. Ganapathi
Asst Professor
Mechanical and Manufacturing Engineering
MSRSAS
Fundamentals of Geometric
Dimensioning and Tolerancing
(Basic GD&T)
Based on ASME Y14.5M
AMT2506
2
M.S Ramaiah School of Advanced Studies - Bengaluru
Session Objectives
At the end of the session delegates should
have understand
•Introduction and need for GD&T
•Terms and definitions
•Symbols and rules of GD&T
•Datum and datum reference frame
•Concept of bonus tolerance
2
M.S Ramaiah School of Advanced Studies - Bengaluru
Session Objectives
At the end of the session delegates should
have understand
•Introduction and need for GD&T
•Terms and definitions
•Symbols and rules of GD&T
•Datum and datum reference frame
•Concept of bonus tolerance
AMT2506
3
Types of Tolerances
General
General Tolerances apply to all dimensions on
a drawing.
Linear
Linear Tolerances refer to specific features
that require more accuracy than general
tolerances provide.
Geometric
Geometric Tolerances are concerned with a
feature’s shape or profile, not its size or dimensions.
M.S Ramaiah School of Advanced Studies - Bengaluru
3
Types of Tolerances
General
General Tolerances apply to all dimensions on
a drawing.
Linear
Linear Tolerances refer to specific features
that require more accuracy than general
tolerances provide.
Geometric
Geometric Tolerances are concerned with a
feature’s shape or profile, not its size or dimensions.
M.S Ramaiah School of Advanced Studies - Bengaluru
AMT2506
4
M.S Ramaiah School of Advanced Studies - Bengaluru
What is an Engineering Drawing?
•An engineering drawing is a document that
communicates a precise description of a part. This
description consists of pictures, words, numbers and
symbols. Together these elements communicate part
information to all drawing users
•Engineering drawing information includes
–Geometry (shape, size and form of the part)
–Critical functional relationships
–Tolerances allowed for proper function
–Material, heat treat, surface coatings
–Part documentation information (part number, revision
level)
4
M.S Ramaiah School of Advanced Studies - Bengaluru
What is an Engineering Drawing?
•An engineering drawing is a document that
communicates a precise description of a part. This
description consists of pictures, words, numbers and
symbols. Together these elements communicate part
information to all drawing users
•Engineering drawing information includes
–Geometry (shape, size and form of the part)
–Critical functional relationships
–Tolerances allowed for proper function
–Material, heat treat, surface coatings
–Part documentation information (part number, revision
level)
AMT2506
5
M.S Ramaiah School of Advanced Studies - Bengaluru
The engineering drawing is the
specification for the component or
assembly and is an important
contractual document with many legal
implications, every line and every
comment is important
What is an Engineering Drawing?
5
M.S Ramaiah School of Advanced Studies - Bengaluru
The engineering drawing is the
specification for the component or
assembly and is an important
contractual document with many legal
implications, every line and every
comment is important
What is an Engineering Drawing?
AMT2506
6
M.S Ramaiah School of Advanced Studies - Bengaluru
Consequences of Poor Drawing
•Drawing errors
cost the
organization in
four ways
–Money
–Time
–Material
–Unhappy
customers
6
M.S Ramaiah School of Advanced Studies - Bengaluru
Consequences of Poor Drawing
•Drawing errors
cost the
organization in
four ways
–Money
–Time
–Material
–Unhappy
customers
AMT2506
7
M.S Ramaiah School of Advanced Studies - Bengaluru
Dimensioning can be divided into three categories:
•general dimensioning,
•geometric dimensioning, and
•surface texture.
The following provides information necessary to begin
to understand geometric dimensioning and
tolerancing (GD&T)
Three Categories of Dimensioning
7
M.S Ramaiah School of Advanced Studies - Bengaluru
Dimensioning can be divided into three categories:
•general dimensioning,
•geometric dimensioning, and
•surface texture.
The following provides information necessary to begin
to understand geometric dimensioning and
tolerancing (GD&T)
Three Categories of Dimensioning
AMT2506
8
M.S Ramaiah School of Advanced Studies - Bengaluru
1935: “American Drawing and Drafting Room Practices”,
18 pages including 2 paragraphs on tolerancing
WWII: High scrap rate (lack of full information and +/- system)
Positional tolerance system (round tolerance zones)
“Dimensional Analysis of Engineering Design”
1940: Draftsman’s Handbook (Chevrolet division)
1945: Ordnance Manual on Dimensioning and Tolerancing,
U.S.Army (used symbols rather than notes)
1946: “SAE Aeronautical Drafting Manual”
(Automotive version in 1952)
1949/53: MIL-STD-8/ MIL-STD-8A (7 basic symbols used)
1966: ANSI Y14.5 (updated in ‘73 replacing notes with symbols)
Geometric Dimensioning & Tolerancing
8
M.S Ramaiah School of Advanced Studies - Bengaluru
1935: “American Drawing and Drafting Room Practices”,
18 pages including 2 paragraphs on tolerancing
WWII: High scrap rate (lack of full information and +/- system)
Positional tolerance system (round tolerance zones)
“Dimensional Analysis of Engineering Design”
1940: Draftsman’s Handbook (Chevrolet division)
1945: Ordnance Manual on Dimensioning and Tolerancing,
U.S.Army (used symbols rather than notes)
1946: “SAE Aeronautical Drafting Manual”
(Automotive version in 1952)
1949/53: MIL-STD-8/ MIL-STD-8A (7 basic symbols used)
1966: ANSI Y14.5 (updated in ‘73 replacing notes with symbols)
Geometric Dimensioning & Tolerancing
AMT2506
9
M.S Ramaiah School of Advanced Studies - Bengaluru
Drawing that does not use GD&T
Why GD&T?
9
M.S Ramaiah School of Advanced Studies - Bengaluru
Drawing that does not use GD&T
Why GD&T?
AMT2506
10
M.S Ramaiah School of Advanced Studies - Bengaluru
Manufactured part
that conforms to
the drawing
(previous slide)
without GD&T
10
M.S Ramaiah School of Advanced Studies - Bengaluru
Manufactured part
that conforms to
the drawing
(previous slide)
without GD&T
AMT2506
11
M.S Ramaiah School of Advanced Studies - Bengaluru
Using English to control part features
11
M.S Ramaiah School of Advanced Studies - Bengaluru
Using English to control part features
AMT2506
12
M.S Ramaiah School of Advanced Studies - Bengaluru
Drawing that uses GD&T gives no room for ambiguity and
is very precise and unique
12
M.S Ramaiah School of Advanced Studies - Bengaluru
Drawing that uses GD&T gives no room for ambiguity and
is very precise and unique
AMT2506
13
M.S Ramaiah School of Advanced Studies - Bengaluru
What is GD&T?
•ASME Y14.5M-1994 GD&T is a language of
symbols used on mechanical drawings to efficiently
and accurately communicate geometry requirements
for features on parts and assemblies.
•GD&T, both ASME Y14.5M-1994 and ISO 8015
series are the only recognized international drawing
standards in use throughout the world.
•
GD&T is the language that designers use to translate design requirements into measurable specifications.
13
M.S Ramaiah School of Advanced Studies - Bengaluru
What is GD&T?
•ASME Y14.5M-1994 GD&T is a language of
symbols used on mechanical drawings to efficiently
and accurately communicate geometry requirements
for features on parts and assemblies.
•GD&T, both ASME Y14.5M-1994 and ISO 8015
series are the only recognized international drawing
standards in use throughout the world.
•
GD&T is the language that designers use to translate design requirements into measurable specifications.
AMT2506
14
M.S Ramaiah School of Advanced Studies - Bengaluru
The Geometric Dimensioning and Tolerancing
System
•Geometric Dimensioning and Tolerancing (GD&T) is an
international language that is used on engineering drawings
to accurately describe a part
•GD&T language consists of a well-defined set of symbols,
rules, definitions and conventions
•GD&T is a precise mathematical language that can be used
to describe the size, form, orientation and location of part
features
•G D & T is an exact language that enables designers to
“say what they mean” through a drawing.
•GD&T is also a design philosophy on how to design and
dimension parts
14
M.S Ramaiah School of Advanced Studies - Bengaluru
The Geometric Dimensioning and Tolerancing
System
•Geometric Dimensioning and Tolerancing (GD&T) is an
international language that is used on engineering drawings
to accurately describe a part
•GD&T language consists of a well-defined set of symbols,
rules, definitions and conventions
•GD&T is a precise mathematical language that can be used
to describe the size, form, orientation and location of part
features
•G D & T is an exact language that enables designers to
“say what they mean” through a drawing.
•GD&T is also a design philosophy on how to design and
dimension parts
AMT2506
15
M.S Ramaiah School of Advanced Studies - Bengaluru
GD&T is a means of dimensioning &
tolerancing a drawing which considers the
function of the part and how this part
functions with related parts
–This allows a drawing to contain a more
defined feature more accurately, without
increasing tolerances
15
M.S Ramaiah School of Advanced Studies - Bengaluru
GD&T is a means of dimensioning &
tolerancing a drawing which considers the
function of the part and how this part
functions with related parts
–This allows a drawing to contain a more
defined feature more accurately, without
increasing tolerances
AMT2506
16
M.S Ramaiah School of Advanced Studies - Bengaluru
•GD&T has increased in practice in last 15 years
because of ISO 9000
- ISO 9000 requires not only that something be required, but
how it is to be controlled. For example, how round does a
round feature have to be?
•GD&T is a system that uses standard symbols to
indicate tolerances that are based on the
feature’s geometry
–Sometimes called feature based dimensioning &
tolerancing or true position dimensioning & tolerancing
•
GD&T practices are specified in ANSI / ASME
Y14.5M-1994
16
M.S Ramaiah School of Advanced Studies - Bengaluru
•GD&T has increased in practice in last 15 years
because of ISO 9000
- ISO 9000 requires not only that something be required, but
how it is to be controlled. For example, how round does a
round feature have to be?
•GD&T is a system that uses standard symbols to
indicate tolerances that are based on the
feature’s geometry
–Sometimes called feature based dimensioning &
tolerancing or true position dimensioning & tolerancing
•
GD&T practices are specified in ANSI / ASME
Y14.5M-1994
AMT2506
17
M.S Ramaiah School of Advanced Studies - Bengaluru
WHEN TO USE GD&T
•When part features are critical to a function or interchangeability
•When functional gauging is desirable
•When datum references are desirable to insure consistency
between design
•When standard interpretation or tolerance is not already implied
•When it allows a better choice of machining processes to be
made for production of a part
17
M.S Ramaiah School of Advanced Studies - Bengaluru
WHEN TO USE GD&T
•When part features are critical to a function or interchangeability
•When functional gauging is desirable
•When datum references are desirable to insure consistency
between design
•When standard interpretation or tolerance is not already implied
•When it allows a better choice of machining processes to be
made for production of a part
AMT2506
18
M.S Ramaiah School of Advanced Studies - Bengaluru
GD&T Benefits
•GD&T provides better product design
•GD&T increases tolerances with cylindrical
tolerance zones
•GD&T allows additional (bonus) tolerances
•GD&T allows the designer to communicate
more clearly
•
GD&T eliminates confusion at inspection
18
M.S Ramaiah School of Advanced Studies - Bengaluru
GD&T Benefits
•GD&T provides better product design
•GD&T increases tolerances with cylindrical
tolerance zones
•GD&T allows additional (bonus) tolerances
•GD&T allows the designer to communicate
more clearly
•
GD&T eliminates confusion at inspection
AMT2506
19
M.S Ramaiah School of Advanced Studies - Bengaluru
How Does GD&T Work?
•Identify part surfaces to serve as origins and provide
specific rules explaining how these surfaces establish
the starting point and direction for measurements.
•Convey the nominal (ideal) distances and orientations
from origins to other surfaces.
•Establish boundaries and/or tolerance zones for
specific attributes of each surface along with specific
rules for conformance.
•Allow dynamic interaction between tolerances (simulating actual assembly possibilities) where
appropriate to maximize tolerances.
19
M.S Ramaiah School of Advanced Studies - Bengaluru
How Does GD&T Work?
•Identify part surfaces to serve as origins and provide
specific rules explaining how these surfaces establish
the starting point and direction for measurements.
•Convey the nominal (ideal) distances and orientations
from origins to other surfaces.
•Establish boundaries and/or tolerance zones for
specific attributes of each surface along with specific
rules for conformance.
•Allow dynamic interaction between tolerances (simulating actual assembly possibilities) where
appropriate to maximize tolerances.
AMT2506
20
Tolerancing systems
1.Coordinate Tolerancing system
2. Geometrical Dimensioning and
Tolerancing system
M.S Ramaiah School of Advanced Studies - Bengaluru
20
Tolerancing systems
1.Coordinate Tolerancing system
2. Geometrical Dimensioning and
Tolerancing system
M.S Ramaiah School of Advanced Studies - Bengaluru
AMT2506
21
M.S Ramaiah School of Advanced Studies - Bengaluru
Coordinate Tolerancing System
•Coordinate Tolerancing is a dimensioning system
where a part feature is located (or defined) by means
of rectangular dimensions with given tolerances
Coordinate Tolerancing
has three shortcomings
1.Square or rectangular
tolerance zones
2.Fixed-size tolerance zones
3.Ambiguous instructions for
inspection
21
M.S Ramaiah School of Advanced Studies - Bengaluru
Coordinate Tolerancing System
•Coordinate Tolerancing is a dimensioning system
where a part feature is located (or defined) by means
of rectangular dimensions with given tolerances
Coordinate Tolerancing
has three shortcomings
1.Square or rectangular
tolerance zones
2.Fixed-size tolerance zones
3.Ambiguous instructions for
inspection
AMT2506
22
Square or Rectangular Tolerance zone
•The hole can be off its nominal location in the diagonal
direction a greater distance than in the vertical and horizontal
direction
•A more logical and function approach is to allow the same
tolerance for a hole location in all directions, creating a
cylindrical tolerance zone
M.S Ramaiah School of Advanced Studies - Bengaluru
22
Square or Rectangular Tolerance zone
•The hole can be off its nominal location in the diagonal
direction a greater distance than in the vertical and horizontal
direction
•A more logical and function approach is to allow the same
tolerance for a hole location in all directions, creating a
cylindrical tolerance zone
M.S Ramaiah School of Advanced Studies - Bengaluru
AMT2506
23
Square or Rectangular Tolerance zone
M.S Ramaiah School of Advanced Studies - Bengaluru
23
Square or Rectangular Tolerance zone
M.S Ramaiah School of Advanced Studies - Bengaluru
AMT2506
24
ROUND TOLERANCE ZONE
M.S Ramaiah School of Advanced Studies - Bengaluru
Rectangular Tolerance Zone Circular Tolerance Zone
0.707
+/- 0.25
+/- 0.25
57% Larger
Tolerance Zone
Circular Tolerance Zone
Rectangular Tolerance Zone
24
ROUND TOLERANCE ZONE
M.S Ramaiah School of Advanced Studies - Bengaluru
Rectangular Tolerance Zone Circular Tolerance Zone
0.707
+/- 0.25
+/- 0.25
57% Larger
Tolerance Zone
Circular Tolerance Zone
Rectangular Tolerance Zone
AMT2506
25
M.S Ramaiah School of Advanced Studies - Bengaluru
COORDINATE V/s ROUND
TOLERANCE ZONE
25
M.S Ramaiah School of Advanced Studies - Bengaluru
COORDINATE V/s ROUND
TOLERANCE ZONE
AMT2506
26
Fixed size tolerance zone
Tolerance for distance between two hole is
fixed irrespective of size of hole.
M.S Ramaiah School of Advanced Studies - Bengaluru
26
Fixed size tolerance zone
Tolerance for distance between two hole is
fixed irrespective of size of hole.
M.S Ramaiah School of Advanced Studies - Bengaluru
AMT2506
27
Ambiguous Inspection
M.S Ramaiah School of Advanced Studies - Bengaluru
27
Ambiguous Inspection
M.S Ramaiah School of Advanced Studies - Bengaluru
AMT2506
28
M.S Ramaiah School of Advanced Studies - Bengaluru
Notes required to make coordinate dimensional
equivalent to GD&T Drawing
28
M.S Ramaiah School of Advanced Studies - Bengaluru
Notes required to make coordinate dimensional
equivalent to GD&T Drawing
AMT2506
29
M.S Ramaiah School of Advanced Studies - Bengaluru
Comparison between GD&T and
Coordinate Tolerancing
29
M.S Ramaiah School of Advanced Studies - Bengaluru
Comparison between GD&T and
Coordinate Tolerancing
AMT2506
30
M.S Ramaiah School of Advanced Studies - Bengaluru
Coordinate Tolerancing Vs. GD&T
Drawing
concept
Coordinate Tolerancing Geometric Tolerancing
Tolerance
zone shape
Condition
Square or rectangular tol zones for hole locations
Results
Less tolerance available for hole
Higher manufacturing costs
Condition
Can use diameter symbol to allow round
tol zones
Results
57% more tol for hole location
Lower manufacturing costs
Tolerance
zone
flexibility
Condition
Tol zone is fixed in size
Results
Functional parts scrapped
Higher operating costs
Condition
Use of MMC modifier allows tol zones to
increase under certain conditions
Results
Functional parts used
Lower operating costs
Ease of
inspection
Condition
Implied datum allows choices for set up when
inspecting the part
Results
Multiple inspectors may get different results
Good parts scrapped, Bad parts accepted
Condition
The datum system communicates one set
up for inspection
Results
Clear instructions for inspection
Eliminates disputes over part acceptance
30
M.S Ramaiah School of Advanced Studies - Bengaluru
Coordinate Tolerancing Vs. GD&T
Drawing
concept
Coordinate Tolerancing Geometric Tolerancing
Tolerance
zone shape
Condition
Square or rectangular tol zones for hole locations
Results
Less tolerance available for hole
Higher manufacturing costs
Condition
Can use diameter symbol to allow round
tol zones
Results
57% more tol for hole location
Lower manufacturing costs
Tolerance
zone
flexibility
Condition
Tol zone is fixed in size
Results
Functional parts scrapped
Higher operating costs
Condition
Use of MMC modifier allows tol zones to
increase under certain conditions
Results
Functional parts used
Lower operating costs
Ease of
inspection
Condition
Implied datum allows choices for set up when
inspecting the part
Results
Multiple inspectors may get different results
Good parts scrapped, Bad parts accepted
Condition
The datum system communicates one set
up for inspection
Results
Clear instructions for inspection
Eliminates disputes over part acceptance
AMT2506
31
M.S Ramaiah School of Advanced Studies - Bengaluru
Introduction to Geometric
Tolerancing Symbols
31
M.S Ramaiah School of Advanced Studies - Bengaluru
Introduction to Geometric
Tolerancing Symbols
AMT2506
32
M.S Ramaiah School of Advanced Studies - Bengaluru
Symbols
•Anyone, regardless of his or her native tongue, can
read and write symbols.
•Symbols mean exactly the same thing to everyone.
•Symbols are so compact they can be placed close to
where they apply, and they reduce clutter.
•Symbols are quicker to draw and easier for computers
to draw automatically.
•
Symbols are easier to spot visually.
32
M.S Ramaiah School of Advanced Studies - Bengaluru
Symbols
•Anyone, regardless of his or her native tongue, can
read and write symbols.
•Symbols mean exactly the same thing to everyone.
•Symbols are so compact they can be placed close to
where they apply, and they reduce clutter.
•Symbols are quicker to draw and easier for computers
to draw automatically.
•
Symbols are easier to spot visually.
AMT2506
33
M.S Ramaiah School of Advanced Studies - Bengaluru
Geometric Characteristic Symbols
•Geometric Characteristic Symbols are set
of fourteen symbols used in the language
of geometric tolerancing
33
M.S Ramaiah School of Advanced Studies - Bengaluru
Geometric Characteristic Symbols
•Geometric Characteristic Symbols are set
of fourteen symbols used in the language
of geometric tolerancing
AMT2506
34
M.S Ramaiah School of Advanced Studies - Bengaluru
Geometric Characteristic Symbols
34
M.S Ramaiah School of Advanced Studies - Bengaluru
Geometric Characteristic Symbols
AMT2506
35
M.S Ramaiah School of Advanced Studies - Bengaluru
Modifiers
•Modifiers communicate additional information about the
drawing or tolerancing of a part
•There are eight modifiers used in geometric tolerancing
35
M.S Ramaiah School of Advanced Studies - Bengaluru
Modifiers
•Modifiers communicate additional information about the
drawing or tolerancing of a part
•There are eight modifiers used in geometric tolerancing
AMT2506
36
M.S Ramaiah School of Advanced Studies - Bengaluru
Introduction to Geometric
Tolerancing Terms
36
M.S Ramaiah School of Advanced Studies - Bengaluru
Introduction to Geometric
Tolerancing Terms
AMT2506
37
M.S Ramaiah School of Advanced Studies - Bengaluru
Maximum Material Condition (MMC)
The condition in which a feature of size contains
the maximum amount of material within the
stated limits of size
for example, minimum hole diameter, maximum
shaft diameter.
.255
.250 + .005
.245
.250 + .005
37
M.S Ramaiah School of Advanced Studies - Bengaluru
Maximum Material Condition (MMC)
The condition in which a feature of size contains
the maximum amount of material within the
stated limits of size
for example, minimum hole diameter, maximum
shaft diameter.
.255
.250 + .005
.245
.250 + .005
AMT2506
38
M.S Ramaiah School of Advanced Studies - Bengaluru
Maximum Material Condition
38
M.S Ramaiah School of Advanced Studies - Bengaluru
Maximum Material Condition
AMT2506
39
M.S Ramaiah School of Advanced Studies - Bengaluru
Least Material Condition (LMC)
The condition in which a feature of size contains
the least amount of material within the stated limits
of size
for example, minimum shaft diameter, maximum
hole diameter
.245
.250 + .005
.255
.250 + .005
39
M.S Ramaiah School of Advanced Studies - Bengaluru
Least Material Condition (LMC)
The condition in which a feature of size contains
the least amount of material within the stated limits
of size
for example, minimum shaft diameter, maximum
hole diameter
.245
.250 + .005
.255
.250 + .005
AMT2506
40
M.S Ramaiah School of Advanced Studies - Bengaluru
40
M.S Ramaiah School of Advanced Studies - Bengaluru
AMT2506
41
M.S Ramaiah School of Advanced Studies - Bengaluru
Maximum Material Condition (MMC)
Least Material Condition (LMC)
41
M.S Ramaiah School of Advanced Studies - Bengaluru
Maximum Material Condition (MMC)
Least Material Condition (LMC)
AMT2506
42
M.S Ramaiah School of Advanced Studies - Bengaluru
Use the figure to fill the value of the MMC and LMC for each
dimension (or indicate, does not apply).
Review Exercise
42
M.S Ramaiah School of Advanced Studies - Bengaluru
Use the figure to fill the value of the MMC and LMC for each
dimension (or indicate, does not apply).
Review Exercise
AMT2506
43
M.S Ramaiah School of Advanced Studies - Bengaluru
Feature
–The general term applied to a physical portion of a
part, such as a surface, pin, tab, hole, or slot
43
M.S Ramaiah School of Advanced Studies - Bengaluru
Feature
–The general term applied to a physical portion of a
part, such as a surface, pin, tab, hole, or slot
AMT2506
44
M.S Ramaiah School of Advanced Studies - Bengaluru
•Feature of Size (FOS)
–One cylindrical or spherical surface, or a set of two
opposed elements or opposed parallel surfaces,
associated with a size dimension. An axis, median
plane or center point can be derived from a feature
of size
44
M.S Ramaiah School of Advanced Studies - Bengaluru
•Feature of Size (FOS)
–One cylindrical or spherical surface, or a set of two
opposed elements or opposed parallel surfaces,
associated with a size dimension. An axis, median
plane or center point can be derived from a feature
of size
AMT2506
45
M.S Ramaiah School of Advanced Studies - Bengaluru
Using the figure, indicate if each letter is associated with a feature
of size dimension or a non-feature of size dimension.
Review Exercise
45
M.S Ramaiah School of Advanced Studies - Bengaluru
Using the figure, indicate if each letter is associated with a feature
of size dimension or a non-feature of size dimension.
Review Exercise
AMT2506
46
M.S Ramaiah School of Advanced Studies - Bengaluru
•Regardless of Feature Size (RFS)
–The term used to indicate that a geometric
tolerance or datum reference applies at any
increment of size of the feature within its size
tolerance.
46
M.S Ramaiah School of Advanced Studies - Bengaluru
•Regardless of Feature Size (RFS)
–The term used to indicate that a geometric
tolerance or datum reference applies at any
increment of size of the feature within its size
tolerance.
AMT2506
47
M.S Ramaiah School of Advanced Studies - Bengaluru
Tolerance Zone on RFS Basis
(Straightness of Axis)
0.05
0.05
0.05
0.05
0.05
0.05
0.05
0.05
47
M.S Ramaiah School of Advanced Studies - Bengaluru
Tolerance Zone on RFS Basis
(Straightness of Axis)
0.05
0.05
0.05
0.05
0.05
0.05
0.05
0.05
AMT2506
48
M.S Ramaiah School of Advanced Studies - Bengaluru
Tolerance Zone on MMC Basis
(Straightness of Axis)
0.11
48
M.S Ramaiah School of Advanced Studies - Bengaluru
Tolerance Zone on MMC Basis
(Straightness of Axis)
0.11
AMT2506
49
M.S Ramaiah School of Advanced Studies - Bengaluru
Bonus Tolerance
•Bonus tolerance is an additional tolerance for a
geometric control
•Bonus tolerance is only permissible when an
MMC (or LMC) modifier is shown in the
tolerance portion of a feature control frame
•Bonus tolerance comes from the FOS tolerance
•Bonus tolerance is the amount the actual
mating size departs from MMC (or LMC)
49
M.S Ramaiah School of Advanced Studies - Bengaluru
Bonus Tolerance
•Bonus tolerance is an additional tolerance for a
geometric control
•Bonus tolerance is only permissible when an
MMC (or LMC) modifier is shown in the
tolerance portion of a feature control frame
•Bonus tolerance comes from the FOS tolerance
•Bonus tolerance is the amount the actual
mating size departs from MMC (or LMC)
AMT2506
50
M.S Ramaiah School of Advanced Studies - Bengaluru
Bonus Tolerance Examples
50
M.S Ramaiah School of Advanced Studies - Bengaluru
Bonus Tolerance Examples
AMT2506
51
M.S Ramaiah School of Advanced Studies - Bengaluru
Bonus Tolerance
51
M.S Ramaiah School of Advanced Studies - Bengaluru
Bonus Tolerance
AMT2506
52
M.S Ramaiah School of Advanced Studies - Bengaluru
Radius and Controlled Radius
•A radius is a straight line extending from the center of an arc
or a circle to its surface
•When “R” symbol is specified, flats or reversals are allowed
•When “CR” symbol is specified, flats or reversals are not allowed
52
M.S Ramaiah School of Advanced Studies - Bengaluru
Radius and Controlled Radius
•A radius is a straight line extending from the center of an arc
or a circle to its surface
•When “R” symbol is specified, flats or reversals are allowed
•When “CR” symbol is specified, flats or reversals are not allowed
AMT2506
53
M.S Ramaiah School of Advanced Studies - Bengaluru
Controlled radius example
CR should only be used in special cases for eg: when the part
stresses are very high and reversals in the radiused surface would
produce higher additional stresses
53
M.S Ramaiah School of Advanced Studies - Bengaluru
Controlled radius example
CR should only be used in special cases for eg: when the part
stresses are very high and reversals in the radiused surface would
produce higher additional stresses
AMT2506
54
M.S Ramaiah School of Advanced Studies - Bengaluru
Actual Local Size and Actual Mating Envelope
(AME)
•Actual Local Size is the value of any individual
distance at any cross section of a FOS
•Actual Mating Envelope (AME) is a variable
value, derived from an actual part
–For an external feature, the actual mating envelope is
the smallest perfect feature counterpart that can be
circumscribed about the feature
–
For an internal feature, the actual mating envelope is the largest perfect feature counterpart that can be inscribed within the feature
54
M.S Ramaiah School of Advanced Studies - Bengaluru
Actual Local Size and Actual Mating Envelope
(AME)
•Actual Local Size is the value of any individual
distance at any cross section of a FOS
•Actual Mating Envelope (AME) is a variable
value, derived from an actual part
–For an external feature, the actual mating envelope is
the smallest perfect feature counterpart that can be
circumscribed about the feature
–
For an internal feature, the actual mating envelope is the largest perfect feature counterpart that can be inscribed within the feature
AMT2506
55
M.S Ramaiah School of Advanced Studies - Bengaluru
Actual Mating Envelope
Internal Feature
External Feature
55
M.S Ramaiah School of Advanced Studies - Bengaluru
Actual Mating Envelope
Internal Feature
External Feature
AMT2506
56
M.S Ramaiah School of Advanced Studies - Bengaluru
Unconstrained Actual Mating Envelope for an external feature
such as a bent cylinder is shown below:
Actual Mating Envelope
56
M.S Ramaiah School of Advanced Studies - Bengaluru
Unconstrained Actual Mating Envelope for an external feature
such as a bent cylinder is shown below:
Actual Mating Envelope
AMT2506
57
M.S Ramaiah School of Advanced Studies - Bengaluru
Actual mating envelope of an external feature of size
57
M.S Ramaiah School of Advanced Studies - Bengaluru
Actual mating envelope of an external feature of size
AMT2506
58
M.S Ramaiah School of Advanced Studies - Bengaluru
Actual mating envelope of an internal feature of size
58
M.S Ramaiah School of Advanced Studies - Bengaluru
Actual mating envelope of an internal feature of size
AMT2506
59
M.S Ramaiah School of Advanced Studies - Bengaluru
Feature control frame
59
M.S Ramaiah School of Advanced Studies - Bengaluru
Feature control frame
AMT2506
60
M.S Ramaiah School of Advanced Studies - Bengaluru
THE
GEOMETRIC SYMBOL
TOLERANCE INFORMATION
DATUM REFERENCES
FEATURE CONTROL FRAME
COMPARTMENT VARIABLES
CONNECTING WORDS
MUST BE WITHIN
OF THE FEATURE
RELATIVE TO
Feature Control Frame
60
M.S Ramaiah School of Advanced Studies - Bengaluru
THE
GEOMETRIC SYMBOL
TOLERANCE INFORMATION
DATUM REFERENCES
FEATURE CONTROL FRAME
COMPARTMENT VARIABLES
CONNECTING WORDS
MUST BE WITHIN
OF THE FEATURE
RELATIVE TO
Feature Control Frame
AMT2506
61
M.S Ramaiah School of Advanced Studies - Bengaluru
61
M.S Ramaiah School of Advanced Studies - Bengaluru
AMT2506
62
M.S Ramaiah School of Advanced Studies - Bengaluru
Feature Control Frame
Reads as: The position of the feature must be within
a .003 diametrical tolerance zone at maximum material
condition relative to datums A, B, and C.
Uses feature
control frames
to indicate
tolerance
62
M.S Ramaiah School of Advanced Studies - Bengaluru
Feature Control Frame
Reads as: The position of the feature must be within
a .003 diametrical tolerance zone at maximum material
condition relative to datums A, B, and C.
Uses feature
control frames
to indicate
tolerance
AMT2506
63
M.S Ramaiah School of Advanced Studies - Bengaluru
Feature Control Frame
Reads as: The position of the feature must be
within a .003 diametrical tolerance zone at
maximum material condition relative to datums
A at maximum material condition and B.
Uses feature
control frames
to indicate
tolerance
63
M.S Ramaiah School of Advanced Studies - Bengaluru
Feature Control Frame
Reads as: The position of the feature must be
within a .003 diametrical tolerance zone at
maximum material condition relative to datums
A at maximum material condition and B.
Uses feature
control frames
to indicate
tolerance
AMT2506
64
M.S Ramaiah School of Advanced Studies - Bengaluru
Placement of Feature Control Frames
May be attached to a side, end or corner of the symbol
box to an extension line.
Applied to surface.
Applied to axis
64
M.S Ramaiah School of Advanced Studies - Bengaluru
Placement of Feature Control Frames
May be attached to a side, end or corner of the symbol
box to an extension line.
Applied to surface.
Applied to axis
AMT2506
65
M.S Ramaiah School of Advanced Studies - Bengaluru
Placement of Feature Control Frames Cont’d.
May be below or closely adjacent to
the dimension or note pertaining to
that feature.
Ø .500.005
65
M.S Ramaiah School of Advanced Studies - Bengaluru
Placement of Feature Control Frames Cont’d.
May be below or closely adjacent to
the dimension or note pertaining to
that feature.
Ø .500.005
AMT2506
66
M.S Ramaiah School of Advanced Studies - Bengaluru
Basic Dimensions
•Basic Dimensions
–can be used to define the theoretically exact location, orientation or true
profile of part features or gage information
–that define part features must be accompanied by a geometric tolerance
–that define gage information do not have a tolerance shown on the print
66
M.S Ramaiah School of Advanced Studies - Bengaluru
Basic Dimensions
•Basic Dimensions
–can be used to define the theoretically exact location, orientation or true
profile of part features or gage information
–that define part features must be accompanied by a geometric tolerance
–that define gage information do not have a tolerance shown on the print
AMT2506
67
M.S Ramaiah School of Advanced Studies - Bengaluru
Basic Dimension
•A theoretically exact size, profile, orientation, or
location of a feature or datum target, therefore, a basic
dimension is untoleranced
•Most often used with position, angularity, and profile
•
Basic dimensions have a rectangle surrounding it.
1.000
67
M.S Ramaiah School of Advanced Studies - Bengaluru
Basic Dimension
•A theoretically exact size, profile, orientation, or
location of a feature or datum target, therefore, a basic
dimension is untoleranced
•Most often used with position, angularity, and profile
•
Basic dimensions have a rectangle surrounding it.
1.000
AMT2506
68
M.S Ramaiah School of Advanced Studies - Bengaluru
Basic Dimension cont’d.
68
M.S Ramaiah School of Advanced Studies - Bengaluru
Basic Dimension cont’d.
AMT2506
69
M.S Ramaiah School of Advanced Studies - Bengaluru
Basic dimension example
69
M.S Ramaiah School of Advanced Studies - Bengaluru
Basic dimension example
AMT2506
70
M.S Ramaiah School of Advanced Studies - Bengaluru
Rules and Concepts of GD&T
70
M.S Ramaiah School of Advanced Studies - Bengaluru
Rules and Concepts of GD&T
AMT2506
71
M.S Ramaiah School of Advanced Studies - Bengaluru
Geometric Tolerance Rule
RULE – 1 (Limits of Size Rule):
Where only a size dimension is given
a)The size dimensions at any cross section must be
within the size tolerance.
b) The surface(s) shall not extend beyond the perfect
form defined by the MMC Size.
c) The form may vary within an envelope between the
MMC and LMC.
RULE – 2
Geometric tolerances are understood to be applied RFS. If MMC or
LMC is required, it must be placed in the feature control frame
.
71
M.S Ramaiah School of Advanced Studies - Bengaluru
Geometric Tolerance Rule
RULE – 1 (Limits of Size Rule):
Where only a size dimension is given
a)The size dimensions at any cross section must be
within the size tolerance.
b) The surface(s) shall not extend beyond the perfect
form defined by the MMC Size.
c) The form may vary within an envelope between the
MMC and LMC.
RULE – 2
Geometric tolerances are understood to be applied RFS. If MMC or
LMC is required, it must be placed in the feature control frame
.
AMT2506
72
M.S Ramaiah School of Advanced Studies - Bengaluru
Rule#1
•There are two general rules in ASME Y14.5M-
1994. The first rule establishes default
conditions for features of size. The second rule
establishes a default material conditions for
feature control frames
•Rule#1: For features of size, where only
tolerance of size is specified, the surfaces shall
not extend beyond a boundary (envelope) of
perfect form at MMC
72
M.S Ramaiah School of Advanced Studies - Bengaluru
Rule#1
•There are two general rules in ASME Y14.5M-
1994. The first rule establishes default
conditions for features of size. The second rule
establishes a default material conditions for
feature control frames
•Rule#1: For features of size, where only
tolerance of size is specified, the surfaces shall
not extend beyond a boundary (envelope) of
perfect form at MMC
AMT2506
73
M.S Ramaiah School of Advanced Studies - Bengaluru
Rule#1 Examples
73
M.S Ramaiah School of Advanced Studies - Bengaluru
Rule#1 Examples
AMT2506
74
M.S Ramaiah School of Advanced Studies - Bengaluru
Rule#1 Examples
74
M.S Ramaiah School of Advanced Studies - Bengaluru
Rule#1 Examples
AMT2506
75
M.S Ramaiah School of Advanced Studies - Bengaluru
•How to Override Rule#1
–A straightness control applied to a FOS
–A special note applied to a FOS
•Rule#1 Limitation
–Rule#1 does not control the location, orientation or
relationship between features of size
75
M.S Ramaiah School of Advanced Studies - Bengaluru
•How to Override Rule#1
–A straightness control applied to a FOS
–A special note applied to a FOS
•Rule#1 Limitation
–Rule#1 does not control the location, orientation or
relationship between features of size
AMT2506
76
M.S Ramaiah School of Advanced Studies - Bengaluru
Rule#2
•Rule#2 is called “the all applicable geometric
tolerance rule”
•Rule#2: RFS applies, with respect to the
individual tolerance, datum reference or both,
where no modifying symbol is specified.
MMC or LMC must be specified on the
drawing where required
76
M.S Ramaiah School of Advanced Studies - Bengaluru
Rule#2
•Rule#2 is called “the all applicable geometric
tolerance rule”
•Rule#2: RFS applies, with respect to the
individual tolerance, datum reference or both,
where no modifying symbol is specified.
MMC or LMC must be specified on the
drawing where required
AMT2506
77
M.S Ramaiah School of Advanced Studies - Bengaluru
77
M.S Ramaiah School of Advanced Studies - Bengaluru
AMT2506
78
Sl
no
Size Form
tolerance
Bonus
tolerance
Total
tolerance
1 11
2 10
3 9
M.S Ramaiah School of Advanced Studies - Bengaluru
Interpretation
Φ10 +/-1
No form tolerance
78
Sl
no
Size Form
tolerance
Bonus
tolerance
Total
tolerance
1 11
2 10
3 9
M.S Ramaiah School of Advanced Studies - Bengaluru
Interpretation
Φ10 +/-1
No form tolerance
AMT2506
79
Sl
no
Size Form
tolerance
Bonus
tolerance
Total
tolerance
1 11
2 10
3 9
M.S Ramaiah School of Advanced Studies - Bengaluru
Interpretation
Φ10 +/-1
--- 0.2
Form tolerance-FCF-
attached to Feature
79
Sl
no
Size Form
tolerance
Bonus
tolerance
Total
tolerance
1 11
2 10
3 9
M.S Ramaiah School of Advanced Studies - Bengaluru
Interpretation
Φ10 +/-1
--- 0.2
Form tolerance-FCF-
attached to Feature
AMT2506
80
Sl
no
Size Form
tolerance
Bonus
tolerance
Total
tolerance
1 11
2 10
3 9
M.S Ramaiah School of Advanced Studies - Bengaluru
Interpretation
Φ10 +/-1
--- 0.2
Form tolerance-FCF-
attached to FOS.
RFS situation
80
Sl
no
Size Form
tolerance
Bonus
tolerance
Total
tolerance
1 11
2 10
3 9
M.S Ramaiah School of Advanced Studies - Bengaluru
Interpretation
Φ10 +/-1
--- 0.2
Form tolerance-FCF-
attached to FOS.
RFS situation
AMT2506
81
Sl
no
Size Form
tolerance
Bonus
tolerance
Total
tolerance
1 11
2 10
3 9
M.S Ramaiah School of Advanced Studies - Bengaluru
Interpretation
Φ10 +/-1
--- 0.2
Form tolerance-FCF-
attached to FOS with
MMC modifier
M
81
Sl
no
Size Form
tolerance
Bonus
tolerance
Total
tolerance
1 11
2 10
3 9
M.S Ramaiah School of Advanced Studies - Bengaluru
Interpretation
Φ10 +/-1
--- 0.2
Form tolerance-FCF-
attached to FOS with
MMC modifier
M
AMT2506
82
Sl
no
Size Form
tolerance
Bonus
tolerance
Total
tolerance
1 11
2 10
3 9
M.S Ramaiah School of Advanced Studies - Bengaluru
Interpretation
Φ10 +/-1
--- 0.2
Form tolerance-FCF-
attached to FOS with
LMC modifier
L
82
Sl
no
Size Form
tolerance
Bonus
tolerance
Total
tolerance
1 11
2 10
3 9
M.S Ramaiah School of Advanced Studies - Bengaluru
Interpretation
Φ10 +/-1
--- 0.2
Form tolerance-FCF-
attached to FOS with
LMC modifier
L
AMT2506
83
M.S Ramaiah School of Advanced Studies - Bengaluru
Datum (Planar)
83
M.S Ramaiah School of Advanced Studies - Bengaluru
Datum (Planar)
AMT2506
84
M.S Ramaiah School of Advanced Studies - Bengaluru
Introduction
•The datum system is a set of symbols and rules
that communicates to the drawing user how
dimensional measurements are to be made
–Datum system allows the designer to specify in
which sequence the part is to contact the inspection
equipment for the measurement of a dimension
–Datum system allows the designer to specify
which part surfaces are to contact the inspection
equipment for the measurement of a dimension
84
M.S Ramaiah School of Advanced Studies - Bengaluru
Introduction
•The datum system is a set of symbols and rules
that communicates to the drawing user how
dimensional measurements are to be made
–Datum system allows the designer to specify in
which sequence the part is to contact the inspection
equipment for the measurement of a dimension
–Datum system allows the designer to specify
which part surfaces are to contact the inspection
equipment for the measurement of a dimension
AMT2506
85
M.S Ramaiah School of Advanced Studies - Bengaluru
•Datum system benefits
–It aids in making repeatable dimensional
measurements
–It aids in communicating part functional
relationships
–It aids in making the dimensional measurement as
intended by the designer
85
M.S Ramaiah School of Advanced Studies - Bengaluru
•Datum system benefits
–It aids in making repeatable dimensional
measurements
–It aids in communicating part functional
relationships
–It aids in making the dimensional measurement as
intended by the designer
AMT2506
86
M.S Ramaiah School of Advanced Studies - Bengaluru
Implied Datum
•An implied datum is an assumed plane axis or
point from which a dimensional measurement
is made and it is an old concept from
coordinate tolerancing
•Consequences of implied datum
–Good parts are rejected
–Bad parts are accepted
86
M.S Ramaiah School of Advanced Studies - Bengaluru
Implied Datum
•An implied datum is an assumed plane axis or
point from which a dimensional measurement
is made and it is an old concept from
coordinate tolerancing
•Consequences of implied datum
–Good parts are rejected
–Bad parts are accepted
AMT2506
87
M.S Ramaiah School of Advanced Studies - Bengaluru
87
M.S Ramaiah School of Advanced Studies - Bengaluru
AMT2506
88
M.S Ramaiah School of Advanced Studies - Bengaluru
Planar Datum
•A datum is a theoretically exact plane, point or
axis from which a dimensional measurement is
made
•A datum feature is a part feature that contacts a
datum
•A planar datum is the true geometric counterpart
of a planar datum feature
•A true geometric counterpart is the theoretical
perfect boundary or best fit tangent plane of a
specified datum feature
88
M.S Ramaiah School of Advanced Studies - Bengaluru
Planar Datum
•A datum is a theoretically exact plane, point or
axis from which a dimensional measurement is
made
•A datum feature is a part feature that contacts a
datum
•A planar datum is the true geometric counterpart
of a planar datum feature
•A true geometric counterpart is the theoretical
perfect boundary or best fit tangent plane of a
specified datum feature
AMT2506
89
M.S Ramaiah School of Advanced Studies - Bengaluru
Planar Datum
89
M.S Ramaiah School of Advanced Studies - Bengaluru
Planar Datum
AMT2506
90
M.S Ramaiah School of Advanced Studies - Bengaluru
Datum Features and Datum
•Datum features are part features and they exist
on the part
•A datum feature simulator is the inspection
equipment that includes the gage elements
used to establish a simulated datum
•Datum are theoretical reference planes or axis
and are simulated by the inspection equipment
•For practical purpose, a simulated datum is
considered a datum
90
M.S Ramaiah School of Advanced Studies - Bengaluru
Datum Features and Datum
•Datum features are part features and they exist
on the part
•A datum feature simulator is the inspection
equipment that includes the gage elements
used to establish a simulated datum
•Datum are theoretical reference planes or axis
and are simulated by the inspection equipment
•For practical purpose, a simulated datum is
considered a datum
AMT2506
91
M.S Ramaiah School of Advanced Studies - Bengaluru
Datum Feature Symbol
•The method of attaching this symbol to a part
feature determines if it designates a planar or a
FOS datum
91
M.S Ramaiah School of Advanced Studies - Bengaluru
Datum Feature Symbol
•The method of attaching this symbol to a part
feature determines if it designates a planar or a
FOS datum
AMT2506
92
M.S Ramaiah School of Advanced Studies - Bengaluru
Referencing Datum in Feature Control
Frames
92
M.S Ramaiah School of Advanced Studies - Bengaluru
Referencing Datum in Feature Control
Frames
AMT2506
93
M.S Ramaiah School of Advanced Studies - Bengaluru
Datum Reference Frame
93
M.S Ramaiah School of Advanced Studies - Bengaluru
Datum Reference Frame
AMT2506
94
M.S Ramaiah School of Advanced Studies - Bengaluru
Datum Reference Frame
94
M.S Ramaiah School of Advanced Studies - Bengaluru
Datum Reference Frame
AMT2506
95
M.S Ramaiah School of Advanced Studies - Bengaluru
Datum Features-Example
95
M.S Ramaiah School of Advanced Studies - Bengaluru
Datum Features-Example
AMT2506
96
M.S Ramaiah School of Advanced Studies - Bengaluru
Primary, Secondary and Tertiary Datum
96
M.S Ramaiah School of Advanced Studies - Bengaluru
Primary, Secondary and Tertiary Datum
AMT2506
97
M.S Ramaiah School of Advanced Studies - Bengaluru
97
M.S Ramaiah School of Advanced Studies - Bengaluru
AMT2506
98
M.S Ramaiah School of Advanced Studies - Bengaluru
3-2-1 Rule
•The 3-2-1 rule defines the minimum points of
contact with the primary datum as 3, the
secondary datum as 2 and the tertiary datum as 1
98
M.S Ramaiah School of Advanced Studies - Bengaluru
3-2-1 Rule
•The 3-2-1 rule defines the minimum points of
contact with the primary datum as 3, the
secondary datum as 2 and the tertiary datum as 1
AMT2506
99
M.S Ramaiah School of Advanced Studies - Bengaluru
Coplanar Datum Features
99
M.S Ramaiah School of Advanced Studies - Bengaluru
Coplanar Datum Features
AMT2506
100
M.S Ramaiah School of Advanced Studies - Bengaluru
Datum (Axis and Centerplane)
100
M.S Ramaiah School of Advanced Studies - Bengaluru
Datum (Axis and Centerplane)
AMT2506
101
M.S Ramaiah School of Advanced Studies - Bengaluru
Datum (Axis and Centerplane)
•When a FOS is used as a datum feature, it
usually results in an axis or a centerplane as
the datum
•When diameter is used as a datum feature, it
results in a datum axis
•When a planar FOS is used as a datum feature,
it results in a datum centerplane
101
M.S Ramaiah School of Advanced Studies - Bengaluru
Datum (Axis and Centerplane)
•When a FOS is used as a datum feature, it
usually results in an axis or a centerplane as
the datum
•When diameter is used as a datum feature, it
results in a datum axis
•When a planar FOS is used as a datum feature,
it results in a datum centerplane
AMT2506
102
M.S Ramaiah School of Advanced Studies - Bengaluru
Placement of datum feature symbols on
Features of Size
102
M.S Ramaiah School of Advanced Studies - Bengaluru
Placement of datum feature symbols on
Features of Size
AMT2506
103
M.S Ramaiah School of Advanced Studies - Bengaluru
Datum (Axis and Centerplane)
103
M.S Ramaiah School of Advanced Studies - Bengaluru
Datum (Axis and Centerplane)
AMT2506
104
M.S Ramaiah School of Advanced Studies - Bengaluru
Datum Targets
•Datum targets are symbols that describe the
shape, size and location of gage elements that
are used to establish datum planes, axis and
points
104
M.S Ramaiah School of Advanced Studies - Bengaluru
Datum Targets
•Datum targets are symbols that describe the
shape, size and location of gage elements that
are used to establish datum planes, axis and
points
AMT2506
105
M.S Ramaiah School of Advanced Studies - Bengaluru
Datum Target Symbols
105
M.S Ramaiah School of Advanced Studies - Bengaluru
Datum Target Symbols
AMT2506
106
M.S Ramaiah School of Advanced Studies - Bengaluru
When to use Datum Targets
•Datum targets should be used whenever
–It is not practical to use the entire surface as a
datum plane
–The designer suspects the part may rock or wobble
when the datum feature contacts the datum plane
–Only a portion of the feature is used in he function
of the part
106
M.S Ramaiah School of Advanced Studies - Bengaluru
When to use Datum Targets
•Datum targets should be used whenever
–It is not practical to use the entire surface as a
datum plane
–The designer suspects the part may rock or wobble
when the datum feature contacts the datum plane
–Only a portion of the feature is used in he function
of the part
AMT2506
107
M.S Ramaiah School of Advanced Studies - Bengaluru
Datum target points
107
M.S Ramaiah School of Advanced Studies - Bengaluru
Datum target points
AMT2506
108
When to use RFS, MMC and LMC ??
•RFS
1.Applied only to those features with an axis or median plane
2.Suitable for dynamic assembly
3.RFS can be applied to interference fit and transitional fit
•MMC
1.Applied only to those features with an axis or median plane
2.Suitable for static assembly
3.MMC can be applied to clearance fit only
•LMC
1.Applied only to those features with an axis or median plane
2.Guarantee minimum wall thickness
M.S Ramaiah School of Advanced Studies - Bengaluru
108
When to use RFS, MMC and LMC ??
•RFS
1.Applied only to those features with an axis or median plane
2.Suitable for dynamic assembly
3.RFS can be applied to interference fit and transitional fit
•MMC
1.Applied only to those features with an axis or median plane
2.Suitable for static assembly
3.MMC can be applied to clearance fit only
•LMC
1.Applied only to those features with an axis or median plane
2.Guarantee minimum wall thickness
M.S Ramaiah School of Advanced Studies - Bengaluru
AMT2506
109
M.S Ramaiah School of Advanced Studies - Bengaluru
LMC guarantees minimum Wall
thickness
109
M.S Ramaiah School of Advanced Studies - Bengaluru
LMC guarantees minimum Wall
thickness
AMT2506
110
When to use RFS, MMC and LMC ??
M.S Ramaiah School of Advanced Studies - Bengaluru
110
When to use RFS, MMC and LMC ??
M.S Ramaiah School of Advanced Studies - Bengaluru
AMT2506
111
M.S Ramaiah School of Advanced Studies - Bengaluru
Virtual Condition and Boundary Conditions
•Virtual Condition (VC) is a worst-case
boundary generated by the collective effects
of a feature of size at MMC or at LMC and
the geometric tolerance for that material
condition.
•The VC of a FOS includes effects of the
size, orientation and location for the FOS.
The VC boundary is related to the datums
that are referenced in the geometric
tolerance used to determine the VC
111
M.S Ramaiah School of Advanced Studies - Bengaluru
Virtual Condition and Boundary Conditions
•Virtual Condition (VC) is a worst-case
boundary generated by the collective effects
of a feature of size at MMC or at LMC and
the geometric tolerance for that material
condition.
•The VC of a FOS includes effects of the
size, orientation and location for the FOS.
The VC boundary is related to the datums
that are referenced in the geometric
tolerance used to determine the VC
AMT2506
112
M.S Ramaiah School of Advanced Studies - Bengaluru
•Inner Boundary (IB) is a worst-case boundary
generated by the smallest feature of size minus the
stated geometric tolerance (and any additional
tolerance, if applicable)
•Outer boundary (OB) is a worst-case boundary
generated by the largest feature of size plus the stated
geometric tolerance (and any additional tolerance, if
applicable)
•Worst-case Boundary (WCB) is a general term to
refer to the extreme boundary of a FOS that is worst-
case for assembly. Depending upon the part
dimensioning, a worst-case boundary can be VC, IB
or OB
112
M.S Ramaiah School of Advanced Studies - Bengaluru
•Inner Boundary (IB) is a worst-case boundary
generated by the smallest feature of size minus the
stated geometric tolerance (and any additional
tolerance, if applicable)
•Outer boundary (OB) is a worst-case boundary
generated by the largest feature of size plus the stated
geometric tolerance (and any additional tolerance, if
applicable)
•Worst-case Boundary (WCB) is a general term to
refer to the extreme boundary of a FOS that is worst-
case for assembly. Depending upon the part
dimensioning, a worst-case boundary can be VC, IB
or OB
AMT2506
113
M.S Ramaiah School of Advanced Studies - Bengaluru
Feature Control Frame Placement
113
M.S Ramaiah School of Advanced Studies - Bengaluru
Feature Control Frame Placement
AMT2506
114
M.S Ramaiah School of Advanced Studies - Bengaluru
MMC Virtual Condition
•VC= MMC + Geometric Tol in the case of
external FOS such as shaft or pin
•VC= MMC - Geometric Tol in the case of
internal FOS such as hole
114
M.S Ramaiah School of Advanced Studies - Bengaluru
MMC Virtual Condition
•VC= MMC + Geometric Tol in the case of
external FOS such as shaft or pin
•VC= MMC - Geometric Tol in the case of
internal FOS such as hole
AMT2506
115
M.S Ramaiah School of Advanced Studies - Bengaluru
MMC VC Examples
115
M.S Ramaiah School of Advanced Studies - Bengaluru
MMC VC Examples
AMT2506
116
M.S Ramaiah School of Advanced Studies - Bengaluru
LMC Virtual Condition
•VC= LMC - Geometric Tol in the case of
external FOS such as shaft or pin
•VC= LMC + Geometric Tol in the case of
internal FOS such as hole
116
M.S Ramaiah School of Advanced Studies - Bengaluru
LMC Virtual Condition
•VC= LMC - Geometric Tol in the case of
external FOS such as shaft or pin
•VC= LMC + Geometric Tol in the case of
internal FOS such as hole
AMT2506
117
M.S Ramaiah School of Advanced Studies - Bengaluru
LMC VC Examples
117
M.S Ramaiah School of Advanced Studies - Bengaluru
LMC VC Examples
AMT2506
118
M.S Ramaiah School of Advanced Studies - Bengaluru
RFS Inner and Outer Boundary
•OB= MMC + Geometric Tol in the case of
external FOS such as shaft or pin
•IB= MMC - Geometric Tol in the case of
internal FOS such as hole
118
M.S Ramaiah School of Advanced Studies - Bengaluru
RFS Inner and Outer Boundary
•OB= MMC + Geometric Tol in the case of
external FOS such as shaft or pin
•IB= MMC - Geometric Tol in the case of
internal FOS such as hole
AMT2506
119
M.S Ramaiah School of Advanced Studies - Bengaluru
RFS Inner and Outer Boundary Examples ???
119
M.S Ramaiah School of Advanced Studies - Bengaluru
RFS Inner and Outer Boundary Examples ???
AMT2506
120
M.S Ramaiah School of Advanced Studies - Bengaluru
Worst-Case Boundary Formulas
120
M.S Ramaiah School of Advanced Studies - Bengaluru
Worst-Case Boundary Formulas
AMT2506
121
M.S Ramaiah School of Advanced Studies - Bengaluru
Identify Features of Size (FOS) and determine their MMC and WCB size values
Review Exercise
121
M.S Ramaiah School of Advanced Studies - Bengaluru
Identify Features of Size (FOS) and determine their MMC and WCB size values
Review Exercise
AMT2506
122
M.S Ramaiah School of Advanced Studies - Bengaluru
122
M.S Ramaiah School of Advanced Studies - Bengaluru
AMT2506
123
M.S Ramaiah School of Advanced Studies - Bengaluru
Summary
•Introduction and need for GD&T
•Terms and definitions
•Symbols and rules of GD&T
•Datum and datum reference frame
•Concept of bonus tolerance
have been studied
Thank You
123
M.S Ramaiah School of Advanced Studies - Bengaluru
Summary
•Introduction and need for GD&T
•Terms and definitions
•Symbols and rules of GD&T
•Datum and datum reference frame
•Concept of bonus tolerance
have been studied
Thank You
Tags
Categories
GeneralDownload
Download Slideshow Get the original presentation fileQuick Actions
Statistics
- Views 17,462
- Slides 123
- Favorites 7
- Age 1276 days
Related Slideshows
22
Pray For The Peace Of Jerusalem and You Will Prosper
RodolfoMoralesMarcuc
32 views
26
Don_t_Waste_Your_Life_God.....powerpoint
chalobrido8
35 views
31
VILLASUR_FACTORS_TO_CONSIDER_IN_PLATING_SALAD_10-13.pdf
JaiJai148317
32 views
14
Fertility awareness methods for women in the society
Isaiah47
30 views
35
Chapter 5 Arithmetic Functions Computer Organisation and Architecture
RitikSharma297999
29 views
5
syakira bhasa inggris (1) (1).pptx.......
ourcommunity56
30 views