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8/10/2019 Simulation Lab Final
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Specify radius of circle or [Diameter] : 10
Command: *Cancel*
Command: ar
ARRAY
Specify center point of array: center of circle
Number of items: 8
Select objects: 1 found
Select objects:
Command: l
LINE Specify first point:
Specify next point or [Undo]: 80
Specify next point or [Undo]: 40
Command: LINE Specify first point:
Specify next point or [Undo]: 45
Specify next point or [Undo]: *Cancel*
Command: c
CIRCLE Specify center point for circle or [3P/2P/Ttr (tan tan radius)]:
Specify radius of circle or [Diameter] : d
Specify diameter of circle : 36
Command: c
Specify radius of circle or [Diameter] : d
Specify diameter of circle : 16
Command: c
Specify radius of circle or [Diameter] : d
Specify diameter of circle : 52
Command: c
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Specify radius of circle or [Diameter] : d
Specify diameter of circle : 26
Command: l
LINE Specify first point: tan
Specify next point or [Undo]: tan
Specify next point or [Undo]: *Cancel*
Command: l
LINE Specify first point: tan
Specify next point or [Undo]: tan
Specify next point or [Undo]: *Cancel*
Command: c
CIRCLE Specify center point for circle or [3P/2P/Ttr (tan tan radius)]: ttr
Specify point on object for first tangent of circle:
Specify point on object for second tangent of circle:
Specify radius of circle : 96
Command: c
CIRCLE Specify center point for circle or [3P/2P/Ttr (tan tan radius)]: ttr
Specify point on object for first tangent of circle:
Specify point on object for second tangent of circle:
Specify radius of circle : 42
Command: Specify opposite corner:
TRIM
Current settings: Projection=UCS, Edge=None
Select cutting edges ... 19 found
Select object to trim or shift-select to extend or
[Fence/Crossing/Project/Edge/eRase/Undo]: Specify opposite corner:
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Select object to trim or shift-select to extend [Fence/Crossing/Project/Edge/eRase/Undo]:
*Cancel*
Result: Hence the object is drawn in AutoCAD software with proper dimensions.
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Experiment -2
Aim:Draw the given figure by using AutoCAD software
Commands used: ortho, line, circle, array, mirror, trim, fillet, offset, erase, dimensions.
Program:
Command: c program
CIRCLE Specify center point for circle or [3P/2P/Ttr (tan tan radius)]:
Specify radius of circle or [Diameter]: d
Specify diameter of circle: 62
Command: c
Specify radius of circle or [Diameter] : d
Specify diameter of circle : 32
Command: c
Specify radius of circle or [Diameter] : d
Specify diameter of circle : 85
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Command: c
Specify radius of circle or [Diameter] : d
Specify diameter of circle : 14
Command: l
LINE Specify first point:
Specify next point or [Undo]: *Cancel*
Command: o
OFFSET
Current settings: Erase source=No Layer=Source OFFSETGAPTYPE=0
Specify offset distance or [Through/Erase/Layer] : 4
Select object to offset or [Exit/Undo] : *cancel*
Command: e
ERASE 1 found
Command: tr
TRIM
Current settings: Projection=UCS, Edge=None
Select cutting edges ... 6 found
Select object to trim or shift-select to extend or
[Fence/Crossing/Project/Edge/eRase/Undo]: *Cancel*
Command: ar
ARRAY
Specify center point of array: center of the circle
Number of items: 6
*Cancel*
Command: tr
TRIM
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Current settings: Projection=UCS, Edge=None
Select cutting edges ... 6 found
Select object to trim or shift-select to extend or
[Fence/Crossing/Project/Edge/eRase/Undo]: Specify opposite corner:
[Fence/Crossing/Project/Edge/eRase/Undo]: *Cancel*
Command: l
LINE Specify first point:
Specify next point or [Undo] : 52
Specify next point or [Undo]: 47
Specify next point or [Close/Undo]: *Cancel*
Command: c
CIRCLE Specify center point for circle or [3P/2P/Ttr (tan tan radius)]:
Specify radius of circle or [Diameter] : 14
Command: c
Specify radius of circle or [Diameter] : 6
Command: Specify opposite corner:
Command: e
ERASE 2 found
Command: mi
MIRROR 2 found
Specify first point of mirror line: Specify second point of mirror line:
Erase source objects? [Yes/No] : enter
Command: Specify opposite corner:
Command: MIRROR 4 found
Specify first point of mirror line: Specify second point of mirror line:
Erase source objects? [Yes/No] : enter
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Command: l
LINE Specify first point:
Specify next point or [Undo]: *Cancel*
Command: LINE Specify first point:
Specify next point or [Undo]: *Cancel*
Command: f
FILLET
Current settings: Mode = TRIM, Radius = 0.0000
Select first object or [Undo/Polyline/Radius/Trim/Multiple]: r
Specify fillet radius : 12 at 4 places
Command: tr
TRIM
Current settings: Projection=UCS, Edge=None
Select cutting edges ... 4 found
Select object to trim or shift-select to extend or
[Fence/Crossing/Project/Edge/eRase/Undo]: Specify opposite corner:
[Fence/Crossing/Project/Edge/eRase/Undo]: *Cancel*
Result: Hence the object is drawn in AutoCAD software with proper dimensions.
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EXPERIMENT _-3
AIM:To create a part model of the object as per the given dimension shown in figure.
Software used:- solid works 2013-14
Commands used:- Rectangle, Line, Arc, Extrude, Extrude Cut, Hole wizard and Fillet
Procedure: 1) Double click the solid works Icon on Desktop to open it.
2) File New Part click ok.
3) Set default unit system as MMGS
4) Select a top plane Right click Select Mode
5) Go to sketch Commands Rectangle Select corner Rectangle
6) Dimension: - smart dimension set the length = 100 mm, width= 40 mm.
7) Go to features Extrude boss/base Direction -1
Blind
Enter valve=10 mm
Select ok
8) Insert new sketch
- Select front face of the part body apply sketch
- Set normal to plane Draw profile on that face by using line
command as shown below
Design the feature by using smart dimensions
9) Go to feature Extrude boss/base Direction-1
Blind select reverse
10 mm (Enter value)
Select Ok
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10) Select front plane- go to sketch mode
Sketch command Rectangle Corner Rectangle
Define the sketch smart dimension: 403.
11) Go to features Extrude cut Direction -1 Select through all
12) Features: - Hole wizard Hole type counter bore
Standard
ANSI Metric
Type
Hex bolt- ANSI B 18.2.3.5 M
Hole specification: - size M8
End condition
Select through all
Tick Ok, then select the face
12 a) wake up the center point
Click the positions tab
Move the cursor on to the circumference of the large arc and Drop it.
Go to feature: - fillet Select the radius as 8 mmSelect the corner edge of base feature Ok
Go to Horizontal Hole type Hole
Standard: - ANSJ Metric
Type: - Drill Sizes
Hole specification: - size 7.0
End condition: - Through all.
Select the Top of bottom plate
Repeat the procedure 1.2 (a) then apply
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Go to feature: - filiet radius 3mm: select the faces as shown in main figure, apply.On body
Right click appearance Body Color Select ok
RESULT: Hence by using above commands the figure is obtained as per given dimensions.
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EXPERIMENT-4AIM: To create a given object by using Solid Works Software using proper commands &
dimensions.
Software used:- Solid Works 2012-13
Command used:- Rectangle, Extrude, Extrude cut, fillet, chamfer, Hole wizard.
Procedure:- 1) Double click the solid works Icon, to open the software.
2) File New Part Ok
3) Unit system set MMGS Ok
4) Select Top plane as Sketch plane. Go to
5) Sketch based feature Rectangle Corner rectangle
Smart dimension set as 130100
6) Go to feature Go to features Extrude Boss Direction -1
20 nm [enter value]
7) Select Top surface of the object as sketch plane and
Sketch based features Rectangle corner Rectangle.
Smart dimension to define a sketch 13020
8) go to features Extrude Boss Direction -1
Blind
70 mm [enter value]
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Ok
9) Features fillet fillet radius -20 mm select corner edges.
10) Select front surface of the object as sketch plane Go to sketch Mode
Sketch feature Rectangle Corner rectangle
Define smart dimensions 6070
11) Go to features: - Extrude Direction Blind 50 mm (enter the value)
12) Select the front face again as sketch plane sketch mode is activated sketc
tools Line command
Draw a profile as shown below by using smart dimensions defined in the figure.
13) Go to feature & Extrude cut direction 1 through all ok.
14) Go to features chamfer select the front edge of the above profile.
Distance 30 mm
Angle 450
Ok
15) Select the left face of the object as sketch plane Sketch mode is activated
Sketch tools Corner Rectangle
By using smart dimension define as 2020 mm
16) Hole wizard Hole type Hole Standard
ANSI metric
Type:-Dill size
Specification 7.0
End Condition through all
Ok
Select the left surface of object selected corner point of rectangle and use positio
tab, circumference of the fillet select center point Ok.
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17) Feature fillet fillet Radius 5 mm Select the remaining faces and click
Ok.
18) Mirror Select mirror face /plane. Bodies to mirror Ok.
19) Save the part-2
RESULT: Hence by using above commands the figure is obtained as per given dimensions.
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EXPERIMENT-5AIM: To create a given object using proper commands & Dimensions with the help of solid
work software.
Software used: - solid works 2012-13
Command used:Line, Rectangle, Hole wizard, Extrude, Shell, Mirror, fillet.
Procedure:1) Double click the solid works Icon, to open the software.
2) File New Part ok
3) Unit system set MMGS ok
4) Select the front plane as sketch plane Sketch feature Line command
Draw the profile as shown below, by using smart dimensions define the object as
shown in figure
5) Feature Extrude Mid plane 90 mm Enter value ok
6) Feature Shell Parameters: - 8 mm Extrude value ok
7) Select the bottom face as sketch plane Sketch features Line command
Draw the profile as shown below and define it by using smart dimension.
8) Feature extrude Blind 8 mm Enter value & ok.
9) Feature Hole Wizard Hole Type: - Hole
Standard: - Ansi metric
Hole specification: - 12.0 mm
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End condition through all
Select the cover Extension face, move the cursor to circumference.
Place the hole at center point
Ok.
10) Feature Mirror-1
Mirror face/plane: - Select Right plane
Feature to mirror: - Select front plane
Features to mirror: - select mirror-1
Ok
11) Features: - Mirror-2
Mirror face/plane: - Select front plane
Feature to mirror: - Select mirror-IOk
12) Select Top plane as sketch plane: - Select features Rectangle
Center Rectangle
Ok
13) Feature Extrude cut: - Through all ok.
14) Features: - Fillet: - Fillet radius:-3 mm
Select the front & back corner edges. Ok.
15) Features: Fillet -2:- Fillet radius:-3mm
Select the faces of the object ok.
Save the parts as part-3
RESULT: Hence by using above commands the figure is obtained as per given dimensions
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EXPERIMENT-6AIM:- To create a given object using proper commands & Dimensions with the help of solid
work software
Software used: -Solid works 2012-13.
Command used: -Line, rectangle, circle, extrude, Extrude cut, hole wizard, filletmirror, offset entities.
Procedure:
1) Double click the solid works Icon, to open it.
2) File New Part Ok
3) Unit system set MMGS Ok
4) Select top plane as sketch plane Sketch feature Rectangle
Center Rectangle Smart dimension 11075
5) Features:-Extrude Blind 12 mm enter value Ok.
6) Select Top face of the 1stpart as sketch plane Sketch
Tools Rectangle Corner rectangle Draw it by using smart
Dimensions 6048.
7) Features Extrude Blind
(110 mm (enter value) ok
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8) Select the right surface of the part-2 as sketch plane sketch tools
Circle draw the circle of diameter 25mm and defines it as shown
in figure by using smart dimensions.
9) Feature Extrude Blind 12 mm (enter value) Ok.
10) Select the top surface as sketch as sketch plane corner rectangle
Define it by using smart dimensions.
11) Feature:-Extrude cut Directions- 1
Select Top face of base object
Ok
12) Feature: - Hole wizard: - Counter bore
Standard ANSI metric
Type Hex bolt ANSI B18.2.35 M
Hole Specification
Size M10
End condition through all
Select the part -3 i.e. cylinder and plane on center ok
13) Fillet: - Fillet radius: - 12 mm select the bottom part of right corner edge
Ok
14) Fillet: - Fillet radius:-3 mm
Select the bottom part and ok
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15) Fillet-3 Fillet radius: - 6 mm
Select the right edges of the part-2 and ok
16) Fillet-4 Fillet radius:-3 mm select the bottom edge of the part-2 and ok
17) Fillet-5 Fillet radius:-3.5 mm select the edges of the part-2 and ok it.
18) Fillet-6 Fillet radius 4 mm, select the inner base edge of the part-2 ok it
19) Feature hole Wizard. Hole type Hole
ANSI metric
Drill size
Hole specification 5.0
End specification blind 10 mm
Select the top face of the part-2 and move the cursor on fillet edges and place center
point place it.Features Hole Wizard Counter Bore
Standard:-ANSI Metric
Type: - HEX Bolt ANSI B18 2.3 5 M
Hole specification: Size- M6
Fit:-Normal
End condition through all ok
Select top surface of the base
move the cursor on fillet circumference
Select the center point ok
Features:-Mirror Mirror face /plane
Select the face-1
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Bodies to Mirror: - Select body ok
Select the front face on sketch plane sketch tool Circle Diameter 80
Features Extrude Blind
3 mm Enter value
Features Mirror Mirror face (or) plane front plane
features to mirror:- Select Extrude-4 i. e circle part ok
Select front face of the object as sketch plane Sketch tools Circle Diameter 60
mm ok
Features Extrude cut through all Ok
Select the front face of the object as sketch plane Sketch tools
draw a circle of diameter 70 mm and convert it as construction. Ok.
Also line command: - Centerline Draw lines from center of the circles at 450only each.Exit the sketch
Features: - Hole wizard Type: - Hole
Standard ANSI metric
Type Drill size
Hole specifications size 5.5
End condition through ok
Front surface select the inter section point construct circle and lines
Save it as part-4 and ok
RESULT: Hence by using above commands the figure is obtained as per given
dimensions
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EXPERIMENT 7
AIM: To assemble the given part by using solid works software
APPARATUS:Insert components, rotate components, matesconcentric, coincident,width
PROCEDURE:
1. Go to Solid works2. Select file New Assembly Ok
3.
Set the default to MMGS4. Insert components Browse select Housing ok5. Insert components Browse select cover_PL&LUG ok6. Select the hole of the cover plug and hole of the housing Mate
Concentric Ok7. Select the inner surface of the cover plug and outer surface of the housing
Mate Coincident Ok8.
Insert components Browse select cover_PL&LUG ok9.
Go to Rotate components Rotate the component
10.Select the hole of the cover plug and hole of the housing MateConcentric Ok
11.
Select the inner surface of the cover plug and outer surface of the housingMate Coincident Ok
12.Insert components Browse select worm gear ok13.Select the surface of the worm gear Mate Advanced settings
width select another surface of the worm gear Tab selectionsselect two inner surfaces of the housing Ok
14.Select hole of the worm gear and hole of the housing MateConcentric Ok
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15.Insert components Browse select worm shaft ok16.Select the surface of the shaft and the hole Mate coincident
Ok17.Insert components Browse select off shaft ok18.Select the surface of the shaft and the hole Mate coincident
Ok
19.
Insert components Browse select cover plate ok20.Select the hole of the cover plate and hole of the housing Mate
Concentric Ok21.Select the inner surface of the cover plate and outer surface of the housing
Mate Coincident Ok22.Save the file
RESULT:Hence the given parts are assembled by using solid works software
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EXPERIMENT 8
Aim:To analyze the given object using proper commands with the help of Solid Works
Software.
Software used: Solid Works 2012-13.
Procedure:
1. Open pump cover
This part represents a cover that will be filled with oil under high pressure.
2. Set the units
Click options and set units to SI.
3. Specify the material
Select AL alloys and click 2014 alloy from list.
4. Define Fixture
Select uppermost faces of four tabs and cylindrical faces of four bolt holes.
5. Define load set
Select pressure for type of load
Right click one of the faces on inside of pump cover.
Click select Tangency.
Set the pressure value and direction.
Set the pressure value to 250 psi.
6.
Create Mesh.
7. Run the Simulation.
8.
Results
Factor of Safety is less than 1, indicating that part is over stressed.
Also view stress and Deformation plots.
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9. Change the material
Right click on 2014 Alloy icon
Click apply/edit material
Change the material
Other alloys
Monel(R) 40010.Update
Click run Simulation
Return the analysis using new material.
Factor of Safety be greater than 1.
11.
Save & close the part.
Result:
Thus, the given object is analyzed by using Solid Works Software.
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Experiment -9Aim:To perform a static analysis on I beam as per the given dimensions using Finite element
modeling and post processing
Software used: FEMAP 10.2
Steps involve: Pre-Processing, Analysis and Post -Processing
Pre-Processing stage:
1. Create a line using projected points as 0,0,0 and 1000, 0,0 ok and then cancel
2.Assign the material property using model- materials select as ANSI Steel
3.Assign property to model using Model- Property : define type of the element as Beam
and select the shape of the beam as I beam with width of top and bottom flanges as
150, 300, and thickness of the flanges are 15mm and total depth of the beam as 500
and thickness of the web as 20mm
4.
For Define load as point load which is acting at end point of the beam with themagnitude of 1000N acting downwards
5. For defining boundary conditions go to Model-Constraints define the boundary
conditions select the first point of the beam and fixed it.
6. For meshing go to status bar Mesh- Mesh control -
7. Status bar Mesh Geometry select curve set as per menu
Ok it, go for methods normal to the view as per window shown
Below and okit.
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Analysis
1.Analysis go to manage and select new ok
2.
And select static analysis and ok analyze-load results and click continue
Post- processing:
1.
View results2. Deformed shape and also observe the shear stress distribution and bending moment
for post processor and select the same mention above.
RESULT:Thus static analysis on the Beam is done as per the given dimensions using Finite
element modeling and post processing
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Experiment -10
Aim:To perform a Static analysis and Modeling or to find frequencies and Eigen values of
cantilever beam of length 2m having rectangular cross-section of 500X250mm2
Software used: FEMAP 10.2
Steps involve:Pre-Processing, Analysis and Post -Processing
Pre-Processing stage:
1 Create a line using projected points as 0,0,0 and 2000, 0,0 ok and then cancel
2 Assign the material property using model- materials select as stainless steel
3
Assign property to model using Model- Property: define type of the element as Beam
and select the shape of the beam as Rectangular beam with width 250mm and total
depth of the beam as 500.
4
For Define load as point load which is acting at end point of the beam with themagnitude of 3000N acting downwards
5 For defining boundary conditions go to Model-Constraints define the boundary
conditions select the first point of the beam and fixed it.
6 For meshing go to status bar Mesh- Mesh control -
7 Status bar Mesh Geometry select curve set as per menu
Ok it, go for methods normal to the view as per window shown
below and ok it.
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Analysis
8.Analysis go to manage and select new ok
9.And select static analysis and ok analyze-load results and click continue
10.Again go for analysis select newand select model/Eigen values ok-load results and
click continue
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Post- processing:
11.View results
12.Deformed shape and also observe the shear stress distribution and bending moment
for post processor and select the same mention above.
13.Bending moment diagram of the cantilever beam is shown below
14.
Natural frequency of the 8th mode shape of the beam as shown below
RESULT:Thus static analysis on the Beam is done as per the given dimensions using Finite
element modeling and post processing
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Experiment -11
Aim:To perform static analysis on the given solid part using Finite element modeling and
post processing
Software used: FEMAP 10.2
Steps involved:Pre-Processing, Analysis and Post -Processing
Pre-Processing stage:
1. Open File and Import solid part from the file which is in IGES format
2.Assign the material using model- materials select as ANSI Steel
3.Assign property to model using Model- Property : define type of the element as Solid
4. Define load as surface load acting on the inner surface of the solid with the magnitude
of 1000N acting towards inner surface
5.
For defining boundary conditions- go to Model-Constraints
define the boundary
conditions select the holes and fixed it.
6.
Status bar Mesh Geometry select solid set as per menu
7. For Analysis go to manage and select new ok
8.And select static analysis and ok analyze-load results and click continue
Post- processing:
9.
View results
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10.Deformed shape and also observe the shear stress distribution and bending moment
for post processor and select the same mention above.
RESULT:Thus static analysis on the solid part is done as per the given dimensions using
Finite element modeling and post processing
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Experiment -12Aim:To perform static analysis on the given solid part using Finite element modeling and
post processing
Software used: FEMAP 10.2
Steps involved:Pre-Processing, Analysis and Post -Processing
Pre-Processing stage:
1. Open File and Import solid part from the file which is in IGES format
2.Assign the material using model- materials select as ANSI Steel
3.Assign property to model using Model- Property : define type of the element as Solid
4. For defining boundary conditions- go to Model-Constraints on the surface-select the
holes and fixed it.
5. Status bar Mesh Geometry select solid set as per menu
6.
Define load at the nodal point with the magnitude of force is 1000N acting downwards7. For Analysis go to manage and select new ok
8.And select static analysis and ok analyze-load results and click continue
Post- processing:
9.View results
10.Deformed shape and also observe the shear stress distribution and bending moment
for post processor and select the same mention above.
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RESULT:Thus static analysis on the solid part is done as per the given dimensions using
Finite element modeling and post processing
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EXPERIMENT NO-13
AIM:To perform rectangular profile milling to generate the component as shown in figure
Commands Used
G00 Rapid Traverse
G01 Liner Interpolation
M03 Spindle rotation (CW) Start
M30Program End with rewind
M03 S2200
STOCK/BLOCK,100,100,15,50,50,15)
TOOL/MILL,5,0,20,0)
COLOR,255,255,255)
G00 X40
Y0
Z5
G01 Z-0.5 F40
X40 Y40X-40
Y40
X-40
Y-40
X40
Y-40
X40 Y0Z5
G00 X0 Y0
M30
RESULT:Thus the rectangular profile milling is performed to generate the component as
shown in the above figure
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EXPERIMENT NO-14
AIM:To perform rectangular profile & window cut milling to generate the component asshown in figure
Commands Used
G00 Rapid Traverse
G01 Liner Interpolation
G03 Circular interpolation
M03 Spindle rotation (CW) Start
M30 End Program
M03 S2200
(STOCK/BLOCK,100,100,15,25,25,15)(TOOL/MILL,5,0,20,0)
(COLOR,255,255,255)G00 X0
Y0
Z5
G01 Z-0.5 F40
X50 F75
Y25
G03 X0 Y25 R25 F40
G01 X0 Y0 F75
Z2
G00 Z10
G00 X65
Y0
Z5
G01 Z-0.5 F40
X65 Y65
X-15Y65
X-15
Y-15
X65
X65 Y0
G00 Z2X0 Y0
M30
RESULT: Thus the rectangular profile and window cut milling is performed to generate the
component as shown in the above figure
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EXPERIMENT NO-15
AIM: To perform rectangular profile & circular pocket milling to generate the component as
shown in figure
Commands Used
G00 Rapid Traverse
G01 Liner Interpolation
G12 - Circular pocket milling
G90 - Absolute programming
M03 Spindle rotation (CW) Start
M30End Program
M03 S2200
(STOCK/BLOCK,100,100,15,50,50,15)
G90
(TOOL/MILL,5,0,20,0)
(COLOR,255,255,255)
G00 X0
Y0
G01 Z-0.5 F40
G12 I2.5 F40
G01 X0 F80
G12 I5 F40G01 X0 F80
G12 I7.5 F40
G01 X0 F80
G12 I10 F40
G01 X0 F80
G12 I12.5 F40
G01 X0 F80
G12 I15 F40
G01 X0 F80
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G12 I17.5 F40
G01 X0 F80
G12 I20 F40
G01 X0 F80
G00 Z5 F40
G00 X40
Y0
Z5G01 Z-0.5 F40
X40 Y40
X-40
Y40
X-40
Y-40
X40
Y-40
X40 Y0
G00 Z5 F40
X0 Y0
M3
RESULT:Thus the rectangular profile and circular pocket milling is performed to generate
the component as shown in the above figure
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EXPERIMENT NO-16
AIM:To perform profile milling to generate the component as shown in figure
Commands Used
G00 Rapid Traverse
G01 Liner Interpolation
G02 Circular interpolation (CW)
M03 Spindle rotation (CW) Start
M21 Mirror wrt Y-Axis
M22 - Mirror wrt X-Axis
M23 Mirror Cancel
M30 End Program
M98Subprogram call
M03 S2200
(STOCK/BLOCK,100,100,12,50,50,12)
(TOOL/MILL,4,0,20,0)
(COLOR,255,255,255)G00 Z5
M98 P302
M21
M98 P302
M22
M98 P302M23
M22
M98 P302
O302
GOO X0 Y0
G01 Z-0.5 F40
G02 X40 Y40 R40X0 Y0 R40
X40 Y0 R40
X0 Y0 R40
X0 Y40 R40
X0 Y0 R40
M30
RESULT:Thus the profile milling is performed to generate the component as shown in the
above figure
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EXPERIMENT NO-17
AIM:To perform step turning operation to generate the component as shown in figure
G21 G98
G28 U0 W0(STOCK/75,25,0,-2)
(TOOL/STANDARD,5,80,0,15,0)M06 T02
M03 S1400
G00 X26 Z2
G90 X24.5 Z-50 F50
X24 Z50
X23.5 Z-50
X23 Z50
X22.5 Z-50
X22 Z50
X21.5 Z-50X21 Z50
X20.5 Z-50
X20 Z50
X19.5 Z-30
X19 Z30
X18.5 Z-30
X18 Z30
X17.5 Z-30
X17 Z30
X16.5 Z-30
X16 Z30
X15.5 Z-30
X15 Z30
X14.5 Z-15
X14 Z15
X13.5 Z-15
X13 Z15
X12.5 Z-15X12 Z15
X11.5 Z-15
X11 Z15
X10.5 Z-15
X10 Z15
G28 U0 W0
M05 M30
RESULT:Thus the step turning operation is performed to generate the component as shown
in figure
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40
EXPERIMENT NO-18
AIM:To perform step turning and taper turning operations to generate the component asshown in figure
(TOOL/STANDARD,5,80,0,15,0)
(COLOR,255,255,255)G21 G98
G28 U0 W0
(STOCK/50,25,0,-2)M03 S1400
G00 X26 Z2
G71 P10 Q20 U0.1 W0.1 F50
N10 G00 X10
G01 Z0
G01 X11 Z-1
G01 Z-8
G02 X17 Z-13 R6
G01 Z-19
G03 X23 Z-24 R6
G01 Z-30
N20 G01 X25 Z-34
G70 P10 Q20
G28 U0 W0
M05 M30
RESULT:Thus the step turning and taper turning operation is performed to generate the
component as shown in figure
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EXPERIMENT NO-19
AIM:To perform threading operation to generate the component as shown in figure
G28 U0 W0
(TOOL/THREAD,60,30,20,90)
M06 T06
M03 S600
G00 X20.2 Z2
G76 P031560 Q50 R0.05
G76 X18.77 Z-20 P613 Q50 F1
G28 U0 W0
M05 M30
RESULT:Thus the threading operation is performed to generate the component as shown in
figure
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EXPERIMENT NO-20
AIM:To perform step turning and threading operation to generate the component as shownin figure
G21 G98
G28 U0 W0
(STOCK/75,25,0,-2)
(TOOL/STANDARD,5,80,0,15,0)
M06 T02
M03 S1400
G00 X26 Z2
G90 X24.5 Z-30 F50
X24
X23.5
X23
X22.5X21.5
X21
X20.5
X20
G28 U0 W0
(TOOL/THREAD,60,30,20,90)
M06 T06
M03 S600
G00 X20.2 Z2
G76 P031560 Q50 R0.05
G76 X18.77 Z-20 P613 Q50 F1
G28 U0 W0M05 M30
RESULT:Thus the step turning and threading operation is performed to generate the
component as shown in figure