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INTRODUCTION TO PRO/ENGINEER

We are in a sophisticated world, where good design is good business. Delivering timely results in

the digital medium is an absolute must for success. Designing complex aesthetics or engineered

shapes is tough work and finding a tool, which can provide exact design intent can be even tougher.

Pro/engineer  is the world leading 3D product development solution. It enables designers and

engineers deliver more innovative and appealing products to the market.

The advanced modeling capabilities of pro/engineer make it significantly superior over other

CAD packages. This type of interactive capability to optimize a design adds a new level to the design

and modeling experience.

Pro/engineer is the world’s leading 3D product development solution, which is developed by

PTC-parametric Technology Corporation-a US based company. This software enables designers and

engineers to bring better products to the market faster.

Pro/engineer takes care of the entire product development process, from creative concept

through detailed product definition to serviceability.

Pro/engineer delivers measurable value to manufacturing companies of all sizes and in all

industries.

Pro/engineer is used in a vast range of industries, from manufacturing of rockets to computer

peripherals. With more than 100,000 seats installed worldwide, many CAD users are exposed toPro/engineer and enjoy using Pro/engineer for its power and capability.

In order to meet the requirements of large and small industries PTC has developed a range of

products which includes

  Pro/engineer

  Wind chill

  PTC project link

  PTC parts link

  PTC dynamic design link

 

Pro/mechanica

  Pro/desktop

  Pro/interlink

  Pro/collaborate

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Pro/engineer: a solid modeler

Pro/engineer is a solid modeler – it develops models as solids, allowing you to work in a three-

dimensional environment. In  Pro/engineer the models have volumes and surface areas. As a solid

modeling tool, pro/engineer  Feature-based

  Associative

  Parametric

Feature Based

Pro/engineer is feature based. Geometry is composed of a series of easily understandable

features. A feature is the smallest building block in a model. Pro/engineer allows building a model

feature one at a time. As you construct your model feature by feature you choose your building blocks

as well as the order you create them in, thus capturing your design intent. Is the motive, the all-driving

force, behind every feature creation. Simple features make us individual parts as wells the overall

model flexible and reliable.

Parametric

Pro/engineer is parametric. It is driven by parameters or variable dimensions. The geometry can

be easily changed by modifying dimensions. Here features are interrelated. Modifications of a single

propagate changes in other features as well, thus preserving design intent. A relationship, known as a

parent/child relationship between features when on feature references another.

Associative

Pro/engineer models are often combinations of various parts, assemblies, drawings and other

objects. Pro/engineer makes all these entities fully associative, that means if you make changes at a

certain level those changes propagate to all the levels. For eg, if you change dimensions on a drawing

the change will be reflected in the associated part.

DIFFERENCE BETWEEN PRO/ENGINEER AND OTHER CAD SYSTEMS

PRO/ENGINEER CONVENTIONAL CAD SYSTEM

  Solid modeling

 

Parametric model  Feature based modeling

  Single data structure and full

associatively.

  Subject oriented sub-modeling

  Wireframe and solid model.

 

Fixed dimension model  Primitive based modeling

  Function-oriented data structures

with format interpreters.

  A single geometric-based sys

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Main window:

When we start pro/engineer, the main window opens on our desktop. We can create our

designs in this window. The four distinct elements of the windows are:

  Pull-down menu

  Tool bar

  Display area

  Message area

Pull-down area

Similar to any of the windows application pro/engineer also has pull-down menu. The

pro/engineer pull-down menus are valid in all modules of pro/engineer.

The menu bar, which is a part of the pro/engineer main window, contains menus with optionsfor crafting, saving and modifying models. It also contains menus with options to set our pro/engineer

environment and configuration options.

Tool bar

The pro/engineer tool bar contains icons of frequently used options from the pull-down menu.

This toolbar gives us quick access to the standard set of options that are available in pull down menu.

We can customize it by adding or removing sets of tools. When we activate any changes to the tool

bar, they will be applicable for all open windows.

Each model tree item contains an icon that reflects its object type, for eg, assembly, part,feature or datum plane (also feature). The icon can also show the display or regeneration status for a

feature, part or assembly for example suppressed or unregenerate.

General procedure to create geometry

To start creating a part that needs to be extruded, you must stat with create

New object button → pick part → give an appropriate name to the part → OK → start with

feature →create → solid (default) → protrusion → extrude (default) → done → one or both sides →

pick a sketch plane (default) → on direction menu, you can choose the command flip, if you want to

reverse the direction or click on okay → choose the default unless otherwise requested → at this pointyou will see the sketcher window. The sketcher is a powerful tool for creating two dimensional shapes.

General procedure to create a cut

To create a cut in a part, the following steps must be taken :

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Feature → create → cut → extrude → solid (default) → done → one side(default) →however, if

the cut needs to be done on both sides then → click on both sides → done → setup new (default) →

plane (default) pick ( select the surface that must be cut) → setup new (default) → on direction menu,

you can choose command flip, if you want to reverse the direction or click on OKAY → choose the

default unless otherwise requested choose your references from the reference box (it helps you to

locate the exact location of cut) → after choosing the geometry of your cut with the correct location

and dimension, click on check mark button on geometry tool bar in order to continue to next step →

click on OK button if the direction of cut is ok. Otherwise flip the direction of cut and then click on ok

button with the next menu, choose the depth of the cut (if the options on the tool bar menu are not

one of your choices, then click button→(to specify the depth in the direction that you want) →enter

the depth value of your cut and click on check mark button → click on preview button of the mouse

and the move the mouse around → if the cut is OK, then click on OK button of the box. You have

completed your cut at this point.

General procedure to create geometry using revolve command:

To start creating a part that needs to be extruded, you must start with

Create new object button → pick part → give an appropriate name to the part → OK → start

with feature → create solid(default) →plane(default) →pick → on direction menu, you can choose the

default unless otherwise requested → choose your references from the reference box →click on

create line button and → pick center line and choose the axis of rotation draw your geometry off of

centre line → click on check mark(continue with the current geometry) the menu manager will ask for

the amount of rotation(choose 360 degree if you need complete rotation of your 2D object) →click on

preview button for reviewing your revolved geometry to preview the part →press the ctrl button on

the keyboard and middle button of the mouse and then move the mouse around→ if the revolved

geometry is OK, button of the box.

General procedure to create a hole:

Feature → create →hole in the menu box, enter the diameter of hole → for the depth choose

thru → all pick a surface for primary reference with the appropriate distances → pick the check mark

button to complete your command→ click on preview button for review you cut to →preview the part

press the ctrl button on the keyboard and middle of the mouse and then move the mouse around. 

General procedure to create a geometry using mirror command:

For symmetrical geometry, we can easily create a duplicate of a section by using mirror

command. Feature → copy → mirror →select(default) → dependent(any change in the first geometry

will automatically change the mirror of it as well) →done → you will be asked to select the geometry

that you want to create the mirror of it → select the geometry → done → you will be asked to select a

plane or to create a datum plane to mirror about → select the

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plane → done → a new geometry which is the mirrored geometry will appear on the opposite side.

General procedure to add rounds:

To add rounds (remove material to the edges in order to remove shape edges) to the edges, the

following steps should be followed

Feature → create → solid → round simple → done → constant edge → chain → done → one by

one → you can pick all visible edges on the geometry that you like to have round edges→ after you

round edges → after you select all edges → click on done select → select done in the check menu → 

enter the specific radius of the round in the radius type menu → click on the check mark → click on

the review to approve your work → click on ok to finalize your work.

General procedure to add chamfer:

To add chamfer, follow the following steps

Feature → create → solid → chamfer → edge → 45*d, d*d. → choose your chamfer dimension

and click on check mark → pick the edges that you like to chamfer → done → select done refs click on

the review to approve your work → click on OK to finalize your work.

General procedure to create patterns:

In order to repeat an entity for numerous times, you need to use the pattern command.

However, the pattern features do not have to be identical copies, but can change in size. There are

three types of patterns that vary over the size, references and intersection of instances. The three

types of patterns are created the same way and are as follows:

Identical patterns-have the same size and the same reference surface, but cannot intersect.

Varying pattern- can vary in size and use different surfaces, but cannot intersect.

General pattern-can vary in size, use different references, intersect each other.

Note: your pattern leader is very important part of construction pattern.

General procedure to create sweeps:

Sweeps is one of the most complicated features that we review in this section. we are able to

create a feature by using an open or closed sweep along a trajectory.

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Feature → create → protrusion → sweep\solid\done\→sketch traj → pick front plane for sketching

plane → default → sketch a rectangular figure. Notice the arrow starting at the left of trajectory. This

arrow shows the starting point and direction of sweep.(do not forget to align the left of trajectory withthe base block) →done → no inn FCs(no inner faces) →now move to second step to create the cross

section of your feature → done preview the sweep → OK.

General procedure to create helical sweeps:

The helical sweeps will enable you to design different type of spring. The basic elements of the

helical sweep are “profile” and “axis” which will define a section that moves up in the direction of

profile and round the axis. Revolve around axis is 360 degrees. The number of turns(distance traveled

along the axis is on completed revolution)is the main attributes for different geometry are as follow:

Pitch: constant or variable

Section: orientation (thru axis or norm to traj)

Direction: right handed or left handed.

Constant profile and constant pitch:

Feature → create → solid → protrusion → advanced solid done → helical sweep → done

constant thru axis right handed → done.

Pick from datum as the sketching plane and top datum plane as the reference plane.

Using helical sweeps to create a screw:

Start defining a solid protrusion. Choose feature → create → solid → protrusion → revolve solid

→ done → one side → done→ pick the sketching plane → then sketch the following feature and make

sure to place center line on axis of rotation with 360 degrees rotation.

After completion of our geometry for the screw, then we start with the following step:

Feature → create → solid cut → advanced solid → done → helical sweep done → constant thru

axis right handed → done. Pick front datum plane as the sketching plane and ok the direction (inward

direction) and default. Select your references as shown.

From sketching menu select create line where you are going to create the cut(you will be able to

see an arrow from the beginning of the line). Place a center line on the vertical axis(center of

screw).create the type of pattern of cut for the screw on the opposite side as shown.

Pick the check mark and review the created screw. It must look like the figure below.

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General procedure to create blends:

Blend is a feature that allows a very smooth transition between specified cross sections. Blend

can be straight parallel or smooth rotation. We start with create → solid → protrusion

blend/solid/done → parallel/regular sec → sketch sec → done straight (if the blend is going to be

straight) or smooth (if the blend is going to be a curved blend) →done. 

Note: Each section is sketched separately.

Pick the sketching plane and sketch the first section such as a square with dimensions 10. After

completion of the first sketch, pick sketch from toolbar then pick feature toll and toggle section from

the menu. The second sketch is a rectangular with dimensions 3 by 2.after completion, it will ask you

for the depth. Give a depth of 20 and preview and finally ok for completion.

RESULT: 

Thus we studied about PRO/ENGINEER. 

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AIM:

To draw a 3D block by using PRO/E.

GENERAL PROCEDURE:

To start creating a part that needs to be extruded, you must start with create:

  New object button → pick part → give an appropriate name to the part → 

OK.

  Start with feature → create → solid (default) → protrusion → extrude (default) done → one

side or both sides → pick a sketching plane (default) → on direction menu, you can choose the

command flip, if you want to reverse the direction or click on Okay → at this point you will see

the sketcher window. . The sketcher is a powerful tool for creating two dimensional shapes.

To create a cut in a part, the following steps must be taken:

  Feature → create → cut → extrude → solid (default) → done → one side (default) → however,

if the cut needs to be done on both sides then → click on both sides → done. 

  Setup new (default) → plane (default) → pick (select the surface that must be cut). 

  Setup new (default) → on direction menu, you can choose the command flip, if you want to

reverse the direction or click on Okay → if the cut is Ok, then click on Ok button of the box. Youhave completed your cut at this point.

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ISOMETRIC VIEW

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RESULT:

Thus the given 3D block has been drawn by using PRO/E.

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AIM:

To draw a 3D block by using PRO/E.

GENERAL PROCEDURE:

To start creating a part that needs to be extruded, you must start with create:

  New object button → pick part → give an appropriate name to the part → 

OK.

  Start with feature → create → solid (default) → protrusion → extrude (default) done → one

side or both sides → pick a sketching plane (default) → on direction menu, you can choose the

command flip, if you want to reverse the direction or click on Okay → at this point you will see

the sketcher window. . The sketcher is a powerful tool for creating two dimensional shapes.

To create a cut in a part, the following steps must be taken:

  Feature → create → cut → extrude → solid (default) → done → one side (default) → however,

if the cut needs to be done on both sides then → click on both sides → done. 

  Setup new (default) → plane (default) → pick (select the surface that must be cut). 

  Setup new (default) → on direction menu, you can choose the command flip, if you want to

reverse the direction or click on Okay → if the cut is Ok, then click on Ok button of the box. You

have completed your cut at this point.

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ISOMETRIC VIEW

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RESULT:

Thus the given 3D block has been drawn by using PRO/E.

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AIM:

To draw a 3D block by using PRO/E.

GENERAL PROCEDURE:

To start creating a part that needs to be extruded, you must start with create:

  New object button → pick part → give an appropriate name to the part → 

OK.

  Start with feature → create → solid (default) → protrusion → extrude (default) done → one

side or both sides → pick a sketching plane (default) → on direction menu, you can choose the

command flip, if you want to reverse the direction or click on Okay → at this point you will see

the sketcher window. . The sketcher is a powerful tool for creating two dimensional shapes.

To create a cut in a part, the following steps must be taken:

  Feature → create → cut → extrude → solid (default) → done → one side (default) → however,

if the cut needs to be done on both sides then → click on both sides → done. 

  Setup new (default) → plane (default) → pick (select the surface that must be cut). 

  Setup new (default) → on direction menu, you can choose the command flip, if you want to

reverse the direction or click on Okay → if the cut is Ok, then click on Ok button of the box. Youhave completed your cut at this point.

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ISOMETRIC VIEW

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RESULT:

Thus the given 3D block has been drawn by using PRO/E.

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AIM:

To draw a 3D block by using PRO/E.

GENERAL PROCEDURE:

To start creating a part that needs to be extruded, you must start with create:

  New object button → pick part → give an appropriate name to the part → 

OK.

  Start with feature → create → solid (default) → protrusion → extrude (default) done → one

side or both sides → pick a sketching plane (default) → on direction menu, you can choose the

command flip, if you want to reverse the direction or click on Okay → at this point you will see

the sketcher window. . The sketcher is a powerful tool for creating two dimensional shapes.

To create a cut in a part, the following steps must be taken:

  Feature → create → cut → extrude → solid (default) → done → one side (default) → however,

if the cut needs to be done on both sides then → click on both sides → done. 

  Setup new (default) → plane (default) → pick (select the surface that must be cut). 

  Setup new (default) → on direction menu, you can choose the command flip, if you want to

reverse the direction or click on Okay → if the cut is Ok, then click on Ok button of the box. Youhave completed your cut at this point.

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ISOMETRIC VIEW

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RESULT:

Thus the given 3D block has been drawn by using PRO/E.

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AIM:

To draw a 3D block by using PRO/E.

GENERAL PROCEDURE:

To start creating a part that needs to be extruded, you must start with create:

  New object button → pick part → give an appropriate name to the part → 

OK.

  Start with feature → create → solid (default) → protrusion → extrude (default) done → one

side or both sides → pick a sketching plane (default) → on direction menu, you can choose the

command flip, if you want to reverse the direction or click on Okay → at this point you will see

the sketcher window. . The sketcher is a powerful tool for creating two dimensional shapes.

To create a cut in a part, the following steps must be taken:

  Feature → create → cut → extrude → solid (default) → done → one side (default) → however,

if the cut needs to be done on both sides then → click on both sides → done. 

  Setup new (default) → plane (default) → pick (select the surface that must be cut). 

  Setup new (default) → on direction menu, you can choose the command flip, if you want to

reverse the direction or click on Okay → if the cut is Ok, then click on Ok button of the box. Youhave completed your cut at this point.

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ISOMETRIC VIEW 

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RESULT:

Thus the given 3D block has been drawn by using PRO/E.

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AIM:

To draw a 3D block by using PRO/E.

GENERAL PROCEDURE:

To start creating a part that needs to be extruded, you must start with create:

  New object button → pick part → give an appropriate name to the part → 

OK.

  Start with feature → create → solid (default) → protrusion → extrude (default) done → one

side or both sides → pick a sketching plane (default) → on direction menu, you can choose the

command flip, if you want to reverse the direction or click on Okay → at this point you will see

the sketcher window. . The sketcher is a powerful tool for creating two dimensional shapes.

To create a cut in a part, the following steps must be taken:

  Feature → create → cut → extrude → solid (default) → done → one side (default) → however,

if the cut needs to be done on both sides then → click on both sides → done. 

  Setup new (default) → plane (default) → pick (select the surface that must be cut). 

  Setup new (default) → on direction menu, you can choose the command flip, if you want to

reverse the direction or click on Okay → if the cut is Ok, then click on Ok button of the box. Youhave completed your cut at this point.

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  ISOMETRIC VIEW 

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RESULT:

Thus the given 3D block has been drawn by using PRO/E.

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AIM:

To draw a 3D block by using PRO/E.

GENERAL PROCEDURE:

To start creating a part that needs to be extruded, you must start with create:

  New object button → pick part → give an appropriate name to the part → 

OK.

  Start with feature → create → solid (default) → protrusion → extrude (default) done → one

side or both sides → pick a sketching plane (default) → on direction menu, you can choose the

command flip, if you want to reverse the direction or click on Okay → at this point you will see

the sketcher window. . The sketcher is a powerful tool for creating two dimensional shapes.

To create a cut in a part, the following steps must be taken:

  Feature → create → cut → extrude → solid (default) → done → one side (default) → however,

if the cut needs to be done on both sides then → click on both sides → done. 

  Setup new (default) → plane (default) → pick (select the surface that must be cut). 

  Setup new (default) → on direction menu, you can choose the command flip, if you want to

reverse the direction or click on Okay → if the cut is Ok, then click on Ok button of the box. You

have completed your cut at this point.

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ISOMETRIC VIEW 

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RESULT:

Thus the given 3D block has been drawn by using PRO/E.

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AIM:

To draw a 3D block by using PRO/E.

GENERAL PROCEDURE:

To start creating a part that needs to be extruded, you must start with create:

  New object button → pick part → give an appropriate name to the part → 

OK.

  Start with feature → create → solid (default) → protrusion → extrude (default) done → one

side or both sides → pick a sketching plane (default) → on direction menu, you can choose the

command flip, if you want to reverse the direction or click on Okay → at this point you will see

the sketcher window. . The sketcher is a powerful tool for creating two dimensional shapes.

To create a cut in a part, the following steps must be taken:

  Feature → create → cut → extrude → solid (default) → done → one side (default) → however,

if the cut needs to be done on both sides then → click on both sides → done. 

  Setup new (default) → plane (default) → pick (select the surface that must be cut). 

  Setup new (default) → on direction menu, you can choose the command flip, if you want to

reverse the direction or click on Okay → if the cut is Ok, then click on Ok button of the box. You

have completed your cut at this point.

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ISOMETRIC VIEW 

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RESULT:

Thus the given 3D block has been drawn by using PRO/E.

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AIM:

To draw a 3D block by using PRO/E.

GENERAL PROCEDURE:

To start creating a part that needs to be extruded, you must start with create:

  New object button → pick part → give an appropriate name to the part → 

OK.

  Start with feature → create → solid (default) → protrusion → extrude (default) done → one

side or both sides → pick a sketching plane (default) → on direction menu, you can choose the

command flip, if you want to reverse the direction or click on Okay → at this point you will see

the sketcher window. . The sketcher is a powerful tool for creating two dimensional shapes.

To create a cut in a part, the following steps must be taken:

  Feature → create → cut → extrude → solid (default) → done → one side (default) → however,

if the cut needs to be done on both sides then → click on both sides → done. 

  Setup new (default) → plane (default) → pick (select the surface that must be cut). 

  Setup new (default) → on direction menu, you can choose the command flip, if you want to

reverse the direction or click on Okay → if the cut is Ok, then click on Ok button of the box. You

have completed your cut at this point.

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ISOMETRIC VIEW 

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RESULT:

Thus the given 3D block has been drawn by using PRO/E.

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AIM:

To draw a 3D block by using PRO/E.

GENERAL PROCEDURE:

To start creating a part that needs to be extruded, you must start with create:

  New object button → pick part → give an appropriate name to the part → 

OK.

  Start with feature → create → solid (default) → protrusion → extrude (default) done → one

side or both sides → pick a sketching plane (default) → on direction menu, you can choose the

command flip, if you want to reverse the direction or click on Okay → at this point you will see

the sketcher window. . The sketcher is a powerful tool for creating two dimensional shapes.

To create a cut in a part, the following steps must be taken:

  Feature → create → cut → extrude → solid (default) → done → one side (default) → however,

if the cut needs to be done on both sides then → click on both sides → done. 

  Setup new (default) → plane (default) → pick (select the surface that must be cut). 

  Setup new (default) → on direction menu, you can choose the command flip, if you want to

reverse the direction or click on Okay → if the cut is Ok, then click on Ok button of the box. Youhave completed your cut at this point.

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ISOMETRIC VIEW

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RESULT:

Thus the given 3D block has been drawn by using PRO/E.

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ISOMETRIC VIEW 

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RESULT:

Thus the given 3D block has been drawn by using PRO/E.

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AIM:

To draw the given parts of Knuckle Joint and assemble the same.

GENERAL PROCEDURE: 

To start creating a part that needs to be extruded, you must start with create:

  New object button → pick part → give an appropriate name to the part → 

OK.

  Start with feature → create → solid (default) → protrusion → extrude (default) done → one

side or both sides → pick a sketching plane (default) → on direction menu, you can choose the

command flip, if you want to reverse the direction or click on Okay → at this point you will see

the sketcher window. . The sketcher is a powerful tool for creating two dimensional shapes.

To create a cut in a part, the following steps must be taken:

  Feature → create → cut → extrude → solid (default) → done → one side (default) → however,

if the cut needs to be done on both sides then → click on both sides → done. 

  Setup new (default) → plane (default) → pick (select the surface that must be cut). 

  Setup new (default) → on direction menu, you can choose the command flip, if you want to

reverse the direction or click on Okay → if the cut is Ok, then click on Ok button of the box. You

have completed your cut at this point.

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ASSEMBLED VIEW:

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GENERAL PROCEDURE FOR ASSEMBLY:

  Feature → create → cut → extrude → solid (default) → done → one side (default) → however,

if the cut needs to be done on both sides then → click on both sides → done. 

  Start assembling the parts by placing a “base component” into an empty assembly file.

  Then use placement  constraints to add each subsequent part and orient it to the base

component.

  These constraints determine whether surfaces and edges are aligned, mated, or offset, and by

what values or limits.

ASSEMBLY CONSTRAINTS:

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The first step in creating an assembly is importing a base component and automatically aligning its part

coordinate system with the assembly’s coordinate system. 

1. 

Click File > New. The New dialog box opens.

2. Select Assembly under Type and enter a name for the assembly. Use the default

template.

3. Click OK. The Pro/ENGINEER main window opens and displays the default assembly

datum planes, all marked with the prefix ASM.

4. Click Insert > Component > Assemble on the main menu. The Open dialog box

opens. 

5. Select first part.prt of the model appears and the Component Placement dashboard

appears.

6. Click the Default constraint set from the Automatic constraint set list to assemble

the first part in the default constraint position. This constraint aligns the part

coordinate system with the assembly coordinate system. You will see the part’s Front,

Right, and Top part datum planes align with their respective assembly datum planes.

The STATUS line indicates that the base component is fully constrained.

7. Accept and save the assembly.

RESULT:

Thus the given Knucle Joint parts are drawn and assembled.

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AIM:

To draw the given parts of universal coupling and assemble the same.

GENERAL PROCEDURE: 

To start creating a part that needs to be extruded, you must start with create:

  New object button → pick part → give an appropriate name to the part → 

OK.

  Start with feature → create → solid (default) → protrusion → extrude (default) done → one

side or both sides → pick a sketching plane (default) → on direction menu, you can choose the

command flip, if you want to reverse the direction or click on Okay → at this point you will see

the sketcher window. . The sketcher is a powerful tool for creating two dimensional shapes.

To create a cut in a part, the following steps must be taken:

  Feature → create → cut → extrude → solid (default) → done → one side (default) → however,

if the cut needs to be done on both sides then → click on both sides → done. 

  Setup new (default) → plane (default) → pick (select the surface that must be cut). 

  Setup new (default) → on direction menu, you can choose the command flip, if you want to

reverse the direction or click on Okay → if the cut is Ok, then click on Ok button of the box. Youhave completed your cut at this point.

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ASSEMBLED VIEW:

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GENERAL PROCEDURE FOR ASSEMBLY:

  Feature → create → cut → extrude → solid (default) → done → one side (default) → however,

if the cut needs to be done on both sides then → click on both sides → done. 

  Start assembling the parts by placing a “base component” into an empty assembly file.

  Then use placement  constraints to add each subsequent part and orient it to the base

component.

  These constraints determine whether surfaces and edges are aligned, mated, or offset, and by

what values or limits.

ASSEMBLY CONSTRAINTS:

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The first step in creating an assembly is importing a base component and automatically aligning its partcoordinate system with the assembly’s coordinate system. 

2. 

Click File > New. The New dialog box opens.

2. Select Assembly under Type and enter a name for the assembly. Use the default

template.

3. Click OK. The Pro/ENGINEER main window opens and displays the default assembly

datum planes, all marked with the prefix ASM.

4. Click Insert > Component > Assemble on the main menu. The Open dialog box

opens. 

5. Select first part.prt of the model appears and the Component Placement dashboard

appears.

6. Click the Default constraint set from the Automatic constraint set list to assemble

the first part in the default constraint position. This constraint aligns the part

coordinate system with the assembly coordinate system. You will see the part’s Front,

Right, and Top part datum planes align with their respective assembly datum planes.

The STATUS line indicates that the base component is fully constrained.

7. Accept and save the assembly.

RESULT:

Thus the given universal coupling parts are drawn and assembled.

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AIM:

To draw the given parts of Flange Coupling and assemble the same.

GENERAL PROCEDURE: 

To start creating a part that needs to be extruded, you must start with create:

  New object button → pick part → give an appropriate name to the part → 

OK.

  Start with feature → create → solid (default) → protrusion → extrude (default) done → one

side or both sides → pick a sketching plane (default) → on direction menu, you can choose the

command flip, if you want to reverse the direction or click on Okay → at this point you will see

the sketcher window. . The sketcher is a powerful tool for creating two dimensional shapes.

To create a cut in a part, the following steps must be taken:

  Feature → create → cut → extrude → solid (default) → done → one side (default) → however,

if the cut needs to be done on both sides then → click on both sides → done. 

  Setup new (default) → plane (default) → pick (select the surface that must be cut). 

  Setup new (default) → on direction menu, you can choose the command flip, if you want to

reverse the direction or click on Okay → if the cut is Ok, then click on Ok button of the box. Youhave completed your cut at this point.

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ASSEMBLED VIEW:

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GENERAL PROCEDURE FOR ASSEMBLY:

  Feature → create → cut → extrude → solid (default) → done → one side (default) → however,

if the cut needs to be done on both sides then → click on both sides → done. 

  Start assembling the parts by placing a “base component” into an empty assembly file.

  Then use placement  constraints to add each subsequent part and orient it to the base

component.

  These constraints determine whether surfaces and edges are aligned, mated, or offset, and by

what values or limits.

ASSEMBLY CONSTRAINTS:

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The first step in creating an assembly is importing a base component and automatically aligning its partcoordinate system with the assembly’s coordinate system. 

3. 

Click File > New. The New dialog box opens.

2. Select Assembly under Type and enter a name for the assembly. Use the default

template.

3. Click OK. The Pro/ENGINEER main window opens and displays the default assembly

datum planes, all marked with the prefix ASM.

4. Click Insert > Component > Assemble on the main menu. The Open dialog box

opens. 

5. Select first part.prt of the model appears and the Component Placement dashboard

appears.

6. Click the Default constraint set from the Automatic constraint set list to assemble

the first part in the default constraint position. This constraint aligns the part

coordinate system with the assembly coordinate system. You will see the part’s Front,

Right, and Top part datum planes align with their respective assembly datum planes.

The STATUS line indicates that the base component is fully constrained.

7. Accept and save the assembly.

RESULT:

Thus the given Flange coupling parts are drawn and assembled.

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AIM:

To draw the given parts of Screw Jack and assemble the same.

GENERAL PROCEDURE: 

To start creating a part that needs to be extruded, you must start with create:

  New object button → pick part → give an appropriate name to the part → 

OK.

  Start with feature → create → solid (default) → protrusion → extrude (default) done → one

side or both sides → pick a sketching plane (default) → on direction menu, you can choose the

command flip, if you want to reverse the direction or click on Okay → at this point you will see

the sketcher window. . The sketcher is a powerful tool for creating two dimensional shapes.

To create a cut in a part, the following steps must be taken:

  Feature → create → cut → extrude → solid (default) → done → one side (default) → however,

if the cut needs to be done on both sides then → click on both sides → done. 

  Setup new (default) → plane (default) → pick (select the surface that must be cut). 

  Setup new (default) → on direction menu, you can choose the command flip, if you want to

reverse the direction or click on Okay → if the cut is Ok, then click on Ok button of the box. Youhave completed your cut at this point.

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ASSEMBLED VIEW:

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GENERAL PROCEDURE FOR ASSEMBLY:

  Feature → create → cut → extrude → solid (default) → done → one side (default) →however,

if the cut needs to be done on both sides then → click on both sides → done. 

  Start assembling the parts by placing a “base component” into an empty assembly file.

  Then use placement  constraints to add each subsequent part and orient it to the base

component.

  These constraints determine whether surfaces and edges are aligned, mated, or offset, and by

what values or limits.

ASSEMBLY CONSTRAINTS:

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The first step in creating an assembly is importing a base component and automatically aligning its part

coordinate system with the assembly’s coordinate system. 

4. 

Click File > New. The New dialog box opens.

2. Select Assembly under Type and enter a name for the assembly. Use the defaulttemplate.

3. Click OK. The Pro/ENGINEER main window opens and displays the default assembly

datum planes, all marked with the prefix ASM.

4. Click Insert > Component > Assemble on the main menu. The Open dialog box

opens. 

5. Select first part.prt of the model appears and the Component Placement dashboard

appears.

6. Click the Default constraint set from the Automatic constraint set list to assemble

the first part in the default constraint position. This constraint aligns the part

coordinate system with the assembly coordinate system. You will see the part’s Front,

Right, and Top part datum planes align with their respective assembly datum planes.

The STATUS line indicates that the base component is fully constrained.

7. Accept and save the assembly.

RESULT:

Thus the given Screw Jack parts are drawn and assembled.

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AIM:

To draw the given parts of Plummer Block and assemble the same.

GENERAL PROCEDURE: 

To start creating a part that needs to be extruded, you must start with create:

  New object button → pick part → give an appropriate name to the part → 

OK.

  Start with feature → create → solid (default) → protrusion → extrude (default) done → one

side or both sides → pick a sketching plane (default) → on direction menu, you can choose the

command flip, if you want to reverse the direction or click on Okay → at this point you will see

the sketcher window. . The sketcher is a powerful tool for creating two dimensional shapes.

To create a cut in a part, the following steps must be taken:

  Feature → create → cut → extrude → solid (default) → done → one side (default) → however,

if the cut needs to be done on both sides then → click on both sides → done. 

  Setup new (default) → plane (default) → pick (select the surface that must be cut). 

  Setup new (default) → on direction menu, you can choose the command flip, if you want to

reverse the direction or click on Okay → if the cut is Ok, then click on Ok button of the box. Youhave completed your cut at this point.

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ASSEMBLED VIEW:

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GENERAL PROCEDURE FOR ASSEMBLY:

  Feature → create → cut → extrude → solid (default) → done → one side (default) → however,

if the cut needs to be done on both sides then → click on both sides → done. 

  Start assembling the parts by placing a “base component” into an empty assembly file.

  Then use placement  constraints to add each subsequent part and orient it to the base

component.

  These constraints determine whether surfaces and edges are aligned, mated, or offset, and by

what values or limits.

ASSEMBLY CONSTRAINTS:

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The first step in creating an assembly is importing a base component and automatically aligning its part

coordinate system with the assembly’s coordinate system. 

5. 

Click File > New. The New dialog box opens.

2. Select Assembly under Type and enter a name for the assembly. Use the default

template.

3. Click OK. The Pro/ENGINEER main window opens and displays the default assembly

datum planes, all marked with the prefix ASM.

4. Click Insert > Component > Assemble on the main menu. The Open dialog box

opens. 

5. Select first part.prt of the model appears and the Component Placement dashboard

appears.

6. Click the Default constraint set from the Automatic constraint set list to assemble

the first part in the default constraint position. This constraint aligns the part

coordinate system with the assembly coordinate system. You will see the part’s Front,

Right, and Top part datum planes align with their respective assembly datum planes.

The STATUS line indicates that the base component is fully constrained.

7. Accept and save the assembly.

RESULT:

Thus the given Plummer Block parts are drawn and assembled.

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AIM:

To Study about Finite element analysis in ANSYS.

FINITE ELEMENT ANALYSIS (FEA) USING ANSYS

Finite element analysis is a method of prediction the behavior of real structure

under specified loads and displacement condition. The finite element modeling is a

Generalization of one displacement or matrix method of structural analysis to two and

three dimensional problems. The basic concept of FEA is considered to be an assembly of

discrete pieces called “element” they are connected together at a finite number of point

(or) nodes. The finite element is a geometrically simplified representation of a small part of

the physical structure. As an example, consider the analysis of the column of machine tool.

The column is shown with its base fixed and concentrated forces applied at the end of the

column. The finite element model is made up of quadrilateral element, triangular element

ad rod Tube element. In limited element analysis the stiffness of each element is calculated

and Global stiffness matrix is calculated. Using the stiffness matrix we can define the load

Deflection relationship. Now we can apply the load can be calculated from the known

Deflection using Hook’s law. 

STEP – 1

Define node element for the given part is shown is fig (a) and the finite model of the

part is shown in fig (b). The comer point (1 to 14) in fig (b) is called as nodes. The element is

numbered from 1 to 7 and inter connected in the model by reference to the Nodes. The

nodes and element together establish the approximate finite element model of the Part.STEP – 2 

Form individual stiffness matrix for each element.

STEP – 3 

Assembly the stiffness matrix and analysis the structure for a given set of

boundary condition.

STEP – 4 

Modify the problem in the light of the result of the analysis and proceed with the

NeXT iteration.STEP – 5

Continue the process till an optimum design is evolved.

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TYPE OF ANALYSIS:

1) 

STATIC AND DYANAMIC ANALYSIS

A Structure model created can be used to predict the behavior of real

Structure under the action of external force. We are measured in terms of Deflection and stress. If

the response is static and if loads are steady then the Analysis is static. When load very with the

analysis is called dynamic Analysis.

2) LINEAR AND NON – LINEAR ALALYSIS

If the properties of structure such as stiffness remain constant during the

Entire analysis, these are called as linear analysis. If these properties are varying the analysis of

linear is called as nonlinear.

3) 

THERMAL ANALYSIS

Finite element analysis can be used for several design and problem involving

Thermal stresses, thermal displacement, heat flow, temperature distribution etc..

4) 

FLUID FLOW ANALYSIS

Finite element can solve several types of fluid flow problems.

5) 

FIELD ANALYSIS

Problem in magnetic and acoustic can be solved by finite element analysis.

PRINCIPLES USED IN FEA:

Using the principal of minimum energy, a displacement function or is chosen in an

Element to obtain a correlation of nodal displacements. A set of linear algebraic equation

Can be formed; since equilibrium is imposed is imposed at every node where unknown Are

the nodal displacements. The stress and strain with in element can then be determined

from this nodal displacement.

ANSYS:

Ansys has comprehensive graphical user interference (GUI) that gives users easy

Interactive access to program function, command, documentation and reference material.

An initiative menu systems help user to navigate through the ANSYS program. User can

impute using a mouse, a keyboard, or a combination.

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ANSYS HELP ENGINEERS TO PERFORM THE FOLLOWINGST TASKS

  Build computer models or transfer cad models for structure, products or

Systems.

  Apply operating load or other design performance condition.

  Study the physical responses such as stress level, temperature distribution or

The impact of electromagnetic fields.

 

Optimize the design early in at development process earlier to reduce

Production costs.

  Do prototype testing in environments where otherwise could be undesirable or

Impossible.

RESULT:

Thus we studied about Finite element analysis in ANSYS.

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AIM:

To create a plane stress bracket and analyze (structural) by using ansys.

PROCEDURE:

Preferences:

Individual disciplines to show in the GUI: click structural

Structural discipline option: Click H-Method

Then click: ok

Preprocessor:

Click Element type-Add/Edit/Delete.

Click Add in the defined element types.

Select Beam in 1st column and 2nd elastic 3 in the 2nd column of the library element types.

Then click ok and click close

Preprocessor:

Click Element type-Add/Delete/Edit.

Click Add in the defined element types.Enter the cross sectional area of the beam (AREA) = 100mm*200mm

Enter the moment of inertia of beam (IZZ) = 100mm*200mm

Enter the height of beam (HEIGHT) = 100mm*200mm

Then Click ok and click close.

Preprocessor:

Click properties –Constant-Isotropic-Ok.

Enter young’s Modulus =2e5 and Poisson’s ratio (major) = 0.3

Then click ok.

Preprocessor:

Click modeling-create-keypoints- In active CS.

Enter X=100cm and Y=0cm and Z=0cm in the location in active CS (1st point)

Click apply enter X=100cm and Y=0cm and Z=0cm in the

Location in active CS (2nd point).

Then click ok.

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LOADING CONDITION:

Preprocessor:

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Click Modeling-Operate-lines-straight lines

Pick two nodes draw line and click ok.

Preprocessor:Click Mesh tool – smart size.

Then set fine = 1.

Click set and select beam then OK.

Click Mesh-Pick all.

Select lines at redefined at and click refine-OK-OK-close.

Solution:

Click analysis type- new analysis.

Click static in the type of analysis.

Then click ok.

Solution:

Click- Loads – Apply- structure- Displacement- On nodes.

Pick the left end of the plane (fixed) and click ok.

Click- Load- Apply- Structure- Force/Moment- Nodes.

Pick the free end of plane and click ok.

Then select FY in direct of force/Moment column and enter- 2000N

In force/momentum column.

Then click ok.

Solution:

Click solve- current- LS=OK- Close.

General post processor:

Click Plot result-Nodal solution.

Select DOF solution in the 1st column and USUM in the 2nd column.

Of the item to be contoured.

Then click ok.

General post processor:

Click Element table- Define table- Add.

Enter sf1 I the user label for item column.Select By sequence num in the 1st Column and select SIMIC in the 2nd Column.

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Enter SMIC,2 in the 3rd column and click apply

Again Enter sf1 I the user label for item column.

Select by sequence num in the 1st column and select SMIC in the 2nd column.

Enter SMIC,8 in the 3rd column and click apply.

Again enter bml in the user label for item column.

Select By sequence num in the 1st column and select SMIC in the 2nd column.

Enter SMIC,6 in the 3rd column and click apply.

Again enter sf2 in the user label for item column.

Select By sequence num in the 1st column and select SMIC in the 2nd Column.

Enter SMIC,12 in the 3rd column and click apply.

Again Enter bm2 in the user label for item column.

General Post processor:

Click Plot result-Line element result.

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RESULT:

Thus the structural analysis of plane stress bracket and analyze using ANSYS is successfully done.

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AIM:

To create a roof truss model and analyze (structural) by using ansys.

PROCEDURE:

Preferences:

Individual disciplines to show in the GUI: click structural

Structural discipline option: Click H-Method

Then click: ok

Preprocessor:

Click Element type-Add/Edit/Delete.

Click Add in the defined element types.

Select Beam in 1st column and 2nd elastic 3 in the 2nd column of the library element types.

Then click ok and click close

Preprocessor:

Click Element type-Add/Delete/Edit.

Click Add in the defined element types.

Enter the cross sectional area of the beam (AREA) = 100mm*200mm

Enter the moment of inertia of beam (IZZ) = 100mm*200mm

Enter the height of beam (HEIGHT) = 100mm*200mmThen Click ok and click close.

Preprocessor:

Click properties –Constant-Isotropic-Ok.

Enter young’s Modulus =2e5 and Poisson’s ratio (major) = 0.3

Then click ok.

Preprocessor:

Click modeling-create-keypoints- In active CS.

Enter X=100cm and Y=0cm and Z=0cm in the location in active CS (1st point)Click apply enter X=100cm and Y=0cm and Z=0cm in the

Location in active CS (2nd point).

Then click ok.

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Preprocessor:

Click Modeling-Operate-lines-straight lines

Pick two nodes draw line and click ok.

Preprocessor:Click Mesh tool – smart size.

Then set fine = 1.

Click set and select beam then OK.

Click Mesh-Pick all.

Select lines at redefined at and click refine-OK-OK-close.

Solution:

Click analysis type- new analysis.

Click static in the type of analysis.

Then click ok.

Solution:

Click- Loads – Apply- structure- Displacement- On nodes.

Pick the left end of the plane (fixed) and click ok.

Click- Load- Apply- Structure- Force/Moment- Nodes.

Pick the free end of plane and click ok.

Then select FY in direct of force/Moment column and enter- 2000N

In force/momentum column.

Then click ok.

Solution:Click solve- current- LS=OK- Close.

General post processor:

Click Plot result-Nodal solution.

Select DOF solution in the 1st column and USUM in the 2nd column.

Of the item to be contoured.

Then click ok.

General post processor:

Click Element table- Define table- Add.

Enter sf1 I the user label for item column.Select By sequence num in the 1st Column and select SIMIC in the 2nd Column.

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SHEAR FORCE DIAGRAM:

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Enter SMIC,2 in the 3rd column and click apply

Again Enter sf1 I the user label for item column.

Select by sequence num in the 1st column and select SMIC in the 2nd column.

Enter SMIC,8 in the 3rd column and click apply.

Again enter bml in the user label for item column.

Select By sequence num in the 1st column and select SMIC in the 2nd column.

Enter SMIC,6 in the 3rd column and click apply.

Again enter sf2 in the user label for item column.

Select By sequence num in the 1st column and select SMIC in the 2nd Column.

Enter SMIC,12 in the 3rd column and click apply.

Again Enter bm2 in the user label for item column.

General Post processor:

Click Plot result-Line element result.

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BENDING MOMENT DIAGRAM:

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RESULT:

Thus the structural analysis of roof truss using ANSYS is successfully done.

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AIM:

To create a structural analysis of cantilever beam by using ansys.

PROCEDURE:

Preferences:

Individual disciplines to show in the GUI: click structural

Structural discipline option: Click H-Method

Then click: ok

Preprocessor:

Click Element type-Add/Edit/Delete.

Click Add in the defined element types.

Select Beam in 1st column and 2nd elastic 3 in the 2nd column of the library element types.

Then click ok and click close

Preprocessor:

Click Element type-Add/Delete/Edit.

Click Add in the defined element types.Enter the cross sectional area of the beam (AREA) = 100mm*200mm

Enter the moment of inertia of beam (IZZ) = 100mm*200mm

Enter the height of beam (HEIGHT) = 100mm*200mm

Then Click ok and click close.

Preprocessor:

Click properties –Constant-Isotropic-Ok.

Enter young’s Modulus =2e5 and Poisson’s ratio (major) = 0.3

Then click ok.

Preprocessor:

Click modeling-create-keypoints- In active CS.

Enter X=100cm and Y=0cm and Z=0cm in the location in active CS (1st point)

Click apply enter X=100cm and Y=0cm and Z=0cm in the

Location in active CS (2nd point).

Then click ok.

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LOADING CONDITION & DISPLACEMENT:

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Preprocessor:

Click Modeling-Operate-lines-straight lines

Pick two nodes draw line and click ok.

Preprocessor:Click Mesh tool – smart size.

Then set fine = 1.

Click set and select beam then OK.

Click Mesh-Pick all.

Select lines at redefined at and click refine-OK-OK-close.

Solution:

Click analysis type- new analysis.

Click static in the type of analysis.

Then click ok.

Solution:

Click- Loads – Apply- structure- Displacement- On nodes.

Pick the left end of the plane (fixed) and click ok.

Click- Load- Apply- Structure- Force/Moment- Nodes.

Pick the free end of plane and click ok.

Then select FY in direct of force/Moment column and enter- 2000N

In force/momentum column.

Then click ok.

Solution:

Click solve- current- LS=OK- Close.General post processor:

Click Plot result-Nodal solution.

Select DOF solution in the 1st column and USUM in the 2nd column.

Of the item to be contoured.

Then click ok.

General post processor:

Click Element table- Define table- Add.

Enter sf1 I the user label for item column.

Select By sequence num in the 1st Column and select SIMIC in the 2nd Column.

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SHEAR FORCE DIAGRAM:

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Enter SMIC,2 in the 3rd column and click apply

Again Enter sf1 I the user label for item column.

Select by sequence num in the 1st column and select SMIC in the 2nd column.

Enter SMIC,8 in the 3rd column and click apply.

Again enter bml in the user label for item column.

Select By sequence num in the 1st column and select SMIC in the 2nd column.

Enter SMIC,6 in the 3rd column and click apply.

Again enter sf2 in the user label for item column.

Select By sequence num in the 1st column and select SMIC in the 2nd Column.

Enter SMIC,12 in the 3rd column and click apply.

Again Enter bm2 in the user label for item column.

General Post processor:

Click Plot result-Line element result.

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BENDING MOMENT DIAGRAM:

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RESULT:

Thus the structural analysis of cantilever beam using ANSYS is successfully done.

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AIM:

To create a structural analysis of simply supported beam by using ansys.

PROCEDURE:

Preferences:

Individual disciplines to show in the GUI: click structural

Structural discipline option: Click H-Method

Then click: ok

Preprocessor:

Click Element type-Add/Edit/Delete.

Click Add in the defined element types.

Select Beam in 1st column and 2nd elastic 3 in the 2nd column of the library element types.

Then click ok and click close

Preprocessor:

Click Element type-Add/Delete/Edit.

Click Add in the defined element types.

Enter the cross sectional area of the beam (AREA) = 100mm*200mm

Enter the moment of inertia of beam (IZZ) = 100mm*200mmEnter the height of beam (HEIGHT) = 100mm*200mm

Then Click ok and click close.

Preprocessor:

Click properties –Constant-Isotropic-Ok.

Enter young’s Modulus =2e5 and Poisson’s ratio (major) = 0.3

Then click ok.

Preprocessor:

Click modeling-create-keypoints- In active CS.

Enter X=100cm and Y=0cm and Z=0cm in the location in active CS (1st point)

Click apply enter X=100cm and Y=0cm and Z=0cm in the

Location in active CS (2nd point).

Then click ok.

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LOADING CONDITION & DISPLACEMENT:

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Preprocessor:

Click Modeling-Operate-lines-straight lines

Pick two nodes draw line and click ok.

Preprocessor:

Click Mesh tool – smart size.

Then set fine = 1.

Click set and select beam then OK.

Click Mesh-Pick all.

Select lines at redefined at and click refine-OK-OK-close.

Solution:

Click analysis type- new analysis.

Click static in the type of analysis.

Then click ok.

Solution:

Click- Loads – Apply- structure- Displacement- On nodes.

Pick the left end of the plane (fixed) and click ok.

Click- Load- Apply- Structure- Force/Moment- Nodes.

Pick the free end of plane and click ok.

Then select FY in direct of force/Moment column and enter- 2000N

In force/momentum column.

Then click ok.

Solution:Click solve- current- LS=OK- Close.

General post processor:

Click Plot result-Nodal solution.

Select DOF solution in the 1st column and USUM in the 2nd column.

Of the item to be contoured.

Then click ok.

General post processor:

Click Element table- Define table- Add.

Enter sf1 I the user label for item column.

Select By sequence num in the 1st Column and select SIMIC in the 2nd Column.

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SHEAR FORCE DIAGRAM:

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Enter SMIC,2 in the 3rd column and click apply

Again Enter sf1 I the user label for item column.

Select by sequence num in the 1st column and select SMIC in the 2nd column.

Enter SMIC,8 in the 3rd column and click apply.

Again enter bml in the user label for item column.

Select By sequence num in the 1st column and select SMIC in the 2nd column.

Enter SMIC,6 in the 3rd column and click apply.

Again enter sf2 in the user label for item column.

Select By sequence num in the 1st column and select SMIC in the 2nd Column.

Enter SMIC,12 in the 3rd column and click apply.

Again Enter bm2 in the user label for item column.

General Post processor:

Click Plot result-Line element result.

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BENDING MOMENT DIAGRAM:

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RESULT:

Thus the structural analysis of simply supported beam using ANSYS is successfully done.

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