SYNOPSIS
Over the years rocker arms have been optimized in its design and
material for better performance. Durability, toughness, high
dimension stability, wear resistance, strength and cost of
materials as well as economic factors are the reasons for
optimization of rocker arm. This paper reviews the various types of
rocker arms, based on published sources from the last 40 years in
order to understand rocker arm for its problem identification and
further optimization. This paper present what rocker arm is, where
it is used and why it is used, History related to rocker arm and it
working is described. Various types of rocker arm used in vehicles
and different materials used for making rocker arm are studied in
this paper. Reasons for Failure of rocker arm are also discussed in
this paper. In fast moving world the time is very important
criteria. But in the manual program time takes more and more for
every work in the world In the production department drawing is
very important for design the various parts. In the manual work,
its takes more time and is also very difficult to draw various
components compare to CAD. So, to avoid these difficulties, CAD
implements for quick & accurate design. Computer aided design
have various packages are Auto CAD, Pro-E, etc. Auto CAD is using
for 2D drawing and Pro-E is the latest implement in CAD, Which is
especially using for 3D modeling. Most of the industry Pro-E is
using for creating a new Design and modification of existing
Design.ANSYS software is used for analyzing the 3d modeling
objects. The ANSYS program has much finite element analysis,
capabilities, ranging from a simple, linear, static analysis to a
complex nonlinear, transient dynamic analysis.
INTRODUCTION
As a rocker arm is acted on by a camshaft lobe, it pushes open
either an intake or exhaust valve [1][2]. This allows fuel and air
to be drawn into the combustion chamber during the intake stroke or
exhaust gases to be expelled during the exhaust stroke. Rocker arms
were first invented in the 19th century and have changed little in
function since then. Improvements have been made, however, in both
efficiencies of operation and construction materials [1] [3]
[4].Rocker arm
A rocker arm is a valve train component in internal combustion
engines. As the arm is acted on by a camshaft lobe, it pushes open
either an intake or exhaust valve. This allows fuel and air to be
drawn into the combustion chamber during the intake stroke or
exhaust gases to be expelled during the exhaust stroke. Rocker arms
were first invented in the 19th century and have changed little in
function since then. Improvements have been made, however, in both
efficiency of operation and construction materials. Many modern
rocker arms are made from stamped steel, though some applications
can make use of heavier duty materials.In many internal combustion
engines, rotational motion is induced in the crank shaft as the
pistons cause it to rotate. This rotation is translated to the
camshaft via a belt or chain. In turn, lobes on the camshaft are
used to push open the valves via rocker arms. This can be achieved
either through direct contact between a camshaft lobe and rocker
arm or indirectly though contact with a lifter driven pushrod.
Overhead cam engines have lobes on the camshaft which contact each
rocker arm directly, while overhead valve engines utilize lifters
and pushrods. In overhead cam engines, the camshaft can be located
in the head, while overhead valve engines have the camshaft in the
block. Both varieties are seen in the US, but regulations have
contributed to the decline of overhead valve applications elsewhere
in the world. Throughout the history of the rocker arm, its
function has been studied and improved upon. These improvements
have resulted in arms that are both more efficient and more
resistant to wear. Some designs can actually use two rocker arms
per valve, while others utilize a "rundle" roller bearing to
depress the valve. These variations in design can result in rocker
arms that look physically different from each other, though every
arm still performs the same basic function. Since energy is
required to move a rocker arm and depress a valve, their weight can
be an important consideration. If a rocker arm is excessively
heavy, it may require too much energy to move. This may prevent the
engine from achieving the desired speed of rotation. The strength
of the material can also be a consideration, as weak material may
stress or wear too quickly. Many automotive applications make use
of stamped steel for these reasons, as this material can provide a
balance between weight and durability. Some applications,
particularly diesel engines, may make use of heavier duty
materials. Engines such as these can operate at higher torques and
lower rotational speeds, allowing such materials as cast iron or
forged carbon steel to be used.
HISTORY
Jonathan "Rundle" Bacon created Rocker arms in the 19th century,
rocker arms have been made with and without "rundle" roller tips
that depress upon the valve, as well as many lightweight and high
strength alloys and bearing configurations for the fulcrum,
striving to increase the RPM limits higher and higher for high
performance applications, eventually lending the benefits of these
race bred technologies to more high-end production vehicles. Even
the design aspects of the rocker arm's geometry has been studied
and changed to maximize the cam information exchange to the valve
which the rocker arm imposes, as set forth by the Miller US Patent,
#4,365,785, issued to James Miller on December 28, 1982, often
referred to as the MID-LIFT Patent. Previously, the specific pivot
points with rocker arm design was based on older and less efficient
theories of over-arching motion which increased wear on valve tips,
valve guides and other valve train components, besides diluting the
effective cam lobe information as it was transferred through the
rocker arm's motion to the valve. Jim Miller's MID-LIFT Patent set
a new standard of rocker arm geometrical precision which defined
and duplicated each engine's specific push-rod to valve attack
angles, then designing the rocker's pivot points so that an exact
perpendicular relationship on both sides of the rocker arm was
attained: with the valve and the pushrod, when the valve was at its
"mid-lift" point of motion [5].
Throughout the history of the rocker arm, its function has been
studied and improved upon. These improvements have resulted in
rocker arms that are both more efficient and more resistant to
wear. Some designs can actually use two rocker arms per valve,
while others utilize a "rundle" roller bearing to depress the
valve. These variations in design can result in rocker arms that
look physically different from each other, though ever y rocker arm
still performs the same basic function.Since energy is required to
move a rocker arm and depress a valve, their weight can be an
important consideration. If a rocker arm is excessively heavy, it
may require too much energy to move. This may prevent the engine
from achieving the desired speed of rotation. The strength of the
material can also be a consideration, as weak material may stress
or wear too quickly. Many automotive applications make use of
stamped steel for these reasons, as this material can provide a
balance between weight and durability. Some applications,
particularly diesel engines, may make use of heavier duty
materials. Engines such as these can operate at higher torques and
lower rotational speeds, allowing such materials as cast iron or
forged carbon steel to be used.
WORKING
The rocker arm is an oscillating lever that conveys radial
movement from the cam lobe into linear movement at the poppet valve
to open it. One end is raised and lowered by a rotating lobe of the
camshaft (either directly or via a tappet (lifter) and pushrod)
while the other end acts on the valve stem. When the camshaft lobe
raises the outside of the arm, the inside presses down on the valve
stem, opening the valve. When the outside of the arm is permitted
to return due to the camshafts rotation, the inside rises, allowing
the valve spring to close the valve [2].
The drive cam is driven by the camshaft. This pushes the rocker
arm up and down about the turn-on pin or rocker shaft. Friction may
be reduced at the point of contact with the valve stem by a roller
cam follower. A similar arrangement transfers the motion via
another roller cam follower to a second rocker arm. This rotates
about the rocker shaft, and transfers the motion via a tappet to
the poppet valve. In this case this opens the intake valve to the
cylinder head.The standard small-block Chevy (SBC) uses a 1.5:1
ratio rocker arm. In other words, the rocker-arm tip(output) moves
1.5 times the displacement of its pushrod socket (input), or
camshaft-lobe lift. The 1.5:1-ratio rocker arm translates 0.350
inches of camshaft-lobe lift into 0.525 inch of valve lift (0.350
inch x 1.5 = 0.525 inch). By increasing the rocker-arm ratio, it's
possible to increase valve lift without ever touching the camshaft.
A 1.6:1-ratio rocker arm translates the same 0.350 inch of
camshaft-lobe lift into 0.560 inch of valve lift (0.350 inch x 1.6
= 0.560 inch). This is a lift increase of about 6.7 percent. Valve
lift can typically be increased as much as 10 percent by increasing
rocker ratio.
Since rocker arms are used to control both the intake and
exhaust valves, swapping high-ratio rocker arms onto an engine
increases both the intake-air command and the exhaust-scavenging
potential. Generally speaking, a bump in rocker-arm ratio results
in a noticeable performance gain. The almighty General knows this;
GM swapped in a set of high-ratio 1.6 (up from the LT1's 1.5)
rockers on the LT4 and later specified the LS7 ratio at a healthy
1.8 (up from the LS2's 1.7).
TYPES OF ROCKER ARM
Rocker arms are of various types, there design and
specifications are different for different types of vehicles
(bikes, cars trucks, etc). Even for same type of vehicle category
rocker arms differs in some way. Types of rocker arm also depend
upon which type of Internal-combustion engine is used in a vehicle
(i.e. Push Rod Engines, Over Head Cam Engines, etc).
A. Stamped Steel Rocker Arm- The Stamped Steel Rocker Arm is
probably the most common style of production Rocker Arm. They are
the easiest and cheapest to manufacture because they are stamped
from one piece of metal. They use a turn-on pivot that holds the
rocker in position with a nut that has a rounded bottom. This is a
very simple way of holding the rocker in place while allowing it to
pivot up and down.
Fig.3. Stamped Steel Rocker Arm
B. Roller Tipped Rocker Arm- The Roller Tipped Rocker Arm is
just as it sounds. They are similar to the Stamped Steel Rocker and
add a roller on the tip of the valve end of the rocker arm. This
allows for less friction, for somewhat more power, and reduced wear
on the valve tip. The Roller Tipped Rocker Arm still uses the turn
-on pivot nut and stud for simplicity. They can also be cast or
machined steel or aluminium.
Fig.4. Roller Tipped Rocker Arm
8
Fig.2. Valve train assembly
IV. ROCKER RATIOA rocker arm is simply a mechanically advantaged
lever that translates camshaft data into valve actuation. The
mechanical advantage is defined by a rocker's ratio.C. Full Roller
Rocker Arm- The Full Roller Rocker Arm is not a stamped steel
rocker. They are either machined steelor aluminium. They replace
the turn-on pivot with bearings. They still use the stud from the
turn-on pivot but they don't use the nut. They have a very short
shaft with bearings on each end (inside the rocker) and the shaft
is bolted securely in place and the bearings allow the rocker to
pivot.
Fig.5. Full Roller Rocker Arm
D. Shaft Rocker Arms- The Shaft Rocker Arms build off of the
Full Roller Rocker Arms. They have a shaft that goes through the
rocker arms. Sometimes the shaft only goes through 2 rocker arms
and sometimes the shaft will go through all of the rocker arms
depending on how the head was manufactured. The reason for using a
s haft is for rigidity. Putting a shaft through the rocker arms is
much more rigid than just using a stud from the head. The more
rigid the valve train, the less the valve train deflection and the
less chance for uncontrolled valve train motion at higher RPM.
Fig.6. Shaft Rocker Arms
E. Centre Pivot Rocker Arms- The Centre Pivot Rocker Arm looks
like a traditional rocker arm but there is a big difference.
Instead of the pushrod pushing up on the lifter, the Cam Shaft is
moved into the head and the Cam Shaft pushes directly up on the
lifter to force the valve down. In this case the pivot point is in
the centre of the rocker arm and the Cam Shaft is on one end of the
rocker arm instead of the pushrod.
F. End Pivot (Finger Follower) Rocker Arms- The End Pivot or
Finger Follower puts the pivot point at the end of the Rocker Arm.
In order for the Cam Shaft to push down on the Rocker Arm is must
be located in the middle of the rocker arm.
MATERIALS
Beyond high ratios and friction-abatement technologies,
performance-rocker-swap talk must include discussions of materials,
strength, and stability. The most common rocker materials are steel
and aluminiumExpounding on the material engineering of rocker arms,
Scooter Brothers, cofounder of Comp Cams, explainssome interesting
facts about steel-bodied rocker arms. Scooter states that
chrome-moly steel, although heavier than other materials, can offer
some design advantages and have much thinner sections than
aluminium due to its superior strength density. Generally speaking,
it takes at least two times the aluminium to approach the strength
of steel. The moment of inertia, or performance mass, of properly
engineered steel parts can actually be close to that of aluminium.
In other words, before jumping for lightweight aluminium rockers,
it's important to realize that the effective weight of a quality
steel unit may be comparable
A. Steel- Many automotive applications make use of steel for
these reasons, as this material can provide a balance between
weight and durability. Stamped steel was the OEM standard for Gen I
and II, while cast steel was and is the standard for Gen III and IV
While these are suitable for OEM and basic performance, the
aftermarket and racing communities demand more exotic options
[1].
B. Anodized-aluminium roller rockers-Nothing screams high
performance more than a set of anodized-aluminium roller rockers,
regardless of their true positive effect
C. High-strength alloy aluminum rocker- High-strength alloy
aluminium rocker arms are good, lightweight performers. Basic
aluminium rocker arms are available with cast-alloy or extruded
bodies, and high-end aluminium rocker arms are available machined
from billet alloys [2].
D. Chrome-moly steel- Chrome-moly steel is a common material for
high-performance parts, and rocker arms are no exception. The
strength and rigidity of this material is hard to beat.
E. High-strength alloy steels- High-strength alloy steels are
used in high-end, precision rocker arms, with rock-like rigidity
for high-rpm race applications.
FAILURE OF ROCKER ARM
Failure of rocker arm is a measure concern as it is one of the
important components of push rod IC engines. Failure usual occurs
at due to fracture at the hole or neck of the rocker arm. Various
other factors are also mentioned below.
1. The fracture occurred at the hole of the rocker arm- The
fracture occurred at the hole of the rocker arm. Multiple- origin
fatigue is the dominant failure mechanism. The spheroidization of
cementite in pearlite makes the hardness of the material of the
failed rocker arms decrease to result in lower fatigue strength.
Initiation and growth of the cracks was facilitated by a
microstructure of low fatigue strength [1].The fracture of rocker
arm at the hole is shown in fig.7.
Fig.7. Fracture at the hole of the rocker arm
2. The fracture occurred at the neck of the rocker arm- The
ultimate tensile strength (UTS) and elongation of the rocker arm
material were 164.0 MPa and 2.5%, respectively. This UTS value is
slightly lower than that of normal die -cast Al alloys. In the
stress measurement test, the compressive stress exhibits the
maximum value at the idling state and decreases as the engine speed
increases. The maximum experimental stress at the neck was _21.0
MPa at the engineidle speed. Hence, this rocker arm is deemed to be
safe in terms of fatigue fracture, taking into consideration the
fatigueendurance limit of 58.8 MPa. The safety factors of this
component are 2.6 and 3.8 based on the fatigue endurance limit and
the modified fatigue endurance limit, respectively, suggesting that
this S.F is appropriate. However, gas porosities introduced during
the die-casting process provide sites of weakness at which
premature fatigue crack initiation and finally fatigue fracture of
this rocker arm can occur. Therefore, it is necessary to control
the melt quality during the die- casting process in order to secure
the safety of this type of rocker arm due to stresses acting on it
[2].
Fig.8. Fracture at the neck of the rocker arm
3. Failure of the rocker arm shaft is caused by the bending
load- FEA results for the failure boundary condition obtained from
orthogonal array indicated that the maximum and minimum stresses
were 711 MPa and 161 MPa, respectively. The stress range was 550
MPa. The stress range obtained from the relationship between
striation spacing and the range of the stress intensity factor was
592.42 MPa. The failure boundary condition estimated by using an
orthogonal array and ANOVA was very useful because the relative
error between the stress ranges obtained fro m striation and the
stress ranges from FEA fell within 7%. Thus this result indicates
Failure of the rocker arm shaft is caused by the bending load
[4].
4. Wear of rocker arm pads- The superior wear resistance of
silicon nitride pads for LPG taxi engines and it was found, that
excessive calcium and phosphorus adsorptions on contact surfaces
lubricated with diesel engine grade oil contained primary type zinc
dialkyldithiophosphate and large amounts of calcium detergent. The
excessive adsorption of some additives caused the micro-pits
observed on the cam noses following every test conducted with that
grade of oil. It is thought that the pits were formed by acid
corrosion following mechanochemical reactions [6].
5. Fatigue failure of rocker arm shaft- Fatigue crack in rocker
arm shaft for passenger car was initiated at through hole and
subsequently propagated along its sidewall. If rocker arm shaft is
operated under actual failure boundary condition, number of cycles
to fracture is expected to be less than 129,650 cycles. The maximum
stress measured in failure region under the most dangerous failure
boundary condition of rocker arm shaft between each loading
condition is 221.2 MPa, which exceeds fatigue limit of 206 MPa and
hence rocker arm shaft with this boundary condition has finite
fatigue life
6. Carbon builds up at the end of valve stem- Due to carbon
build up at the end of valve stem. Valve guide wear occurs on the
inside diameter of the valve guide in a straight line with the
centre line of the rocker arm.
7. Failure due to friction- The continuous interaction with the
valve stem and push rod cause friction as they are touching each
other this result in cheap formation.
introduction to CAD/CAMCAD/CAM is a term which means
computer-aided design and computer-aided manufacturing. It is the
technology concerned with the use of digital computers to perform
certain functions in design and production. This technology is
moving in the direction of greater integration of design and
manufacturing, two activities which have traditionally been treated
as district and separate functions in a production firm.
Ultimately, CAD/CAM will provide the technology base for the
computer-integrated factory of the future.Computer aided design
(CAD) can be defined as the use of computer systems to assist in
the creation, modification, analysis, or optimization of a design.
The computer systems consist of the hardware and software to
perform the specialized design functions required by the particular
user firm. The CAD hardware typically includes the computer, one or
more graphics display terminals, keyboards, and other peripheral
equipment. The CAD software consists of the computer programs to
implement computer graphics on the system plus application programs
to facilitate the engineering functions of the user company.
Examples of these application programs include stress-strain
analysis of components, dynamic response of mechanisms,
heat-transfer calculations, and numerical control part
programming.Computer-aided manufacturing (CAM) can be defined as
the use of computer systems to plan, manage, and control the
operations of manufacturing plant through either direct or indirect
computer interface with the plants production resources.
DESIGN PROCESS:The process of designing is characterized by six
identifiable steps or phase1. Recognition of need2. Definition of
problem3. Synthesis 4. Analysis and optimization5. Evaluation6.
PresentationAPPLICATION OF COMPUTERS FOR DESIGN:The various
design-related tasks which are performed by a modern computer-aided
design system can be grouped into four functional areas:1.
Geometric modeling2. Engineering analysis3. Design review and
evaluation4. Automated draftingGeometric Modeling:In computer-aided
design, geometric modeling is concerned with the computer-
compatible mathematical description of the geometry of an object.
The mathematical description allows the image of the object to be
displayed and manipulated on a graphics terminal through signals
from the CPU of the CAD system. The software that provides
geometric modeling capabilities must be designed for efficient use
both by the computer and the human designer.There are several
different methods of representing the object in geometric modeling.
The basic form uses wire frames to represent the object. Wire frame
geometric modeling is classified into three types, depending on the
capabilities of the interactive computer graphics system. The three
types are: 2D- Two Dimensional representation is used for a flat
object. 2D- This goes somewhat beyond the 2D capability by
permitting a three-dimensional object to be represented as long as
it has no side wall details. 3D- This allows for full three
dimensional modeling of a more complex geometry.The most advanced
method of geometric modeling is solid modeling in three dimensions.
Another feature of some CAD systems is color graphics capability.
By means of color, it is possible to display more information on
the graphics screen. Colored images help to clarify components in
an assembly, or highlight dimensions, or a host of other
purposes.i. ENGINEERING ANALYSIS:CAD/CAM systems often include or
can be interfaced to engineering analysis software which can be
called to operate on the current design model. Examples of this
type are Analysis of mass properties Finite element analysisThe
analysis may involve stress strain calculations, heat-transfer
computations, or the use of differential equations to describe the
dynamic behavior of the system being designed.7. Introduction to
Pro-EngineerPro-Engineer is a powerful application. It is ideal for
capturing the design intent of your models because at its
foundation is a practical philosophy. Founder of this Pro-Engineer
is Parametric Technology Corporation. After this version they are
released Pro-E 2000i2, Pro-E 2001, Pro-e Wildfire, Pro-e
Wildfire1.0, Pro-e Wildfire2.0,Pro-e Wildfire3.0,Pro-e
Wildfire4.0,Pro-e Wildfire5.0, Creo Element pro 5.0, Creo 1.0 &
Creo 2.0.7.1 SCREEN LAY OUT:7.1.1. Main Window:When the Pro-E is
started, the main window opens on desktop. The four distinct
elements of the window are:Pull-down menu Tool bar Display area
Message area7.1.1.1 Pull-Down Menus:The Pro-E pull-down menus are
valid in all modes of the system.File:Contains commands for
manipulating filesEdit:Contain action commands.
View:Contains commands for controlling model display and display
performance.Datum:Creates datum features.Analysis:Provide access to
options for model, surface, curve and motion analysis, as well as
sensitivity and optimization studies.Info:Contains commands for
performing queries and generating reports.Application:Provide
access to various Pro-E modules.Utilities:Contains commands for
customizing our working environment.Windows:Contains commands for
managing various Pro-E windows.Help:Contains commands for accessing
online documentation.Tool bar: The Pro-E toolbar contains icons for
frequently used options from the pull-down Menus. The tool bar is
also customized.7.1.1.2 Display area:Pro-E displays parts,
assemblies, drawings, and models on the screen in the display area.
An objects on the current environment settings.7.1.1.3 Message
area:The message area between the toolbar and the display area
performs multiple Functions by: Providing status information for
every operation performed. Providing queries/hints for additional
information to complete a command/task.Displaying icons in the
message area, which represent different forms of information such
as warnings or status prompts. Sketcher Sketcher consists of Sketch
Dimension Constrain Modify Move Delete Geometric Tools Section
Tools Undo Redo
SKETCH:The sketch includes basic geometrical primitives such as
Point Line Rectangle Arc Circle Advanced geometrywhich are used in
two dimensional as well as three dimensional drawing.Point:It has
been drawn by picking the point directly on desired
place.Line:There are two options to draw a lineGeometry Centerline
Both geometry and center line has the following options 2 points 2
tangentRectangle:Rectangle is drawn directly using the command
rectangle.
Arc:The following are the options in drawing the arc: Tangent
End Concentric 3 tangent FilletCircle:There are two basic types of
drawing a circle. They are geometry and construction.Both the above
said types include the following options Center/point Concentric 3
tangent Fillet 3 pointAdvanced geometry:It includes several
advanced features such as Conic Coordinate system Elliptic fillet
Ellipse Spline Text Axis pointDIMENSIONING:Dimensions can be added
to sections as before. When a dimension is added, a weak dimension
or constraint will be removed automatically. Although extra
dimensions are no longer allowed, it is now possible to make
reference dimensions in Sketcher. MODIFYING DIMENSIONS:When
dimension values are modified, the section is updated immediately.
If we don't want the section to update until we have modified
several dimensions, we have to choose Delay Modify first. After the
desired changes have been made, Regenerate should be chosen.
MOVE:The Move command allows modifying the section by dragging an
entity or vertex to a new position without having to specify which
dimensions to be changed. Move will automatically determine which
dimensions to be varied so that the section changes in a natural
way while preserving all constraints. Move can also be used to drag
a dimension to a different location. DELETE:Delete command is used
to remove the features from the basic window. Delete has many
options such as Delete item Delete many Delete all GEOMETRIC
TOOLS:Geometric tool has the following options: Intersect Trim
Divide Use edge Offset edge Mirror Move entitySECTION TOOLS:
Section tool has the following options: Copy draw Integrate Place
section Start point Toggle UndoAll Sketcher operations can now be
undone with the Undo command. We can hit Undo repeatedly to reverse
actions one after another. Redo is provided, as well. 7.1.2
PART:PROTRUSION:Protrusion consists of following options: Extrude
Revolve Sweep BlendEXTRUDE:Extrusion means adding the material from
a specified side.Condition: The drawn sketch must be a closed loop.
Enough references should be mentioned. Protrusion adds the material
perpendicular to the selected plane. Options for giving
depth.Blind:By choosing the option blind, we can give directly
numerical value.Thru until:Adds the material that goes through all
the surfaces until it reaches the specified surface.Up to
point/vertex:Adds the material with a flat bottom that continues
until it reaches the specified point or vertex.Up to Curve:Adds the
material with a flat bottom that continues until it reaches the
specified curve that you draw in a plane parallel to the placement
plane.Up to Surface:Add the material from the selected plane to the
selected surface.Exemption:For the basic (first) component, there
is no option for giving thru next, thru all and thru until. There
is no chance for giving two side blends if one side was
chosen.REVOLVE:The revolve option creates a feature by revolving
the sketched section around a centerline. A revolved feature can be
created either entirely on one side of the sketching plane, or
symmetrically on both sides of the sketching plane.To create or
redefine a revolved feature, specify the elements in the following
order: Attributes Section Direction AngleRules for sketching a
revolved feature: The revolved section must have a centerline. The
geometry must be sketched on only one side of the axis of
revolution. If more than one centerline in the sketch, Pro-E uses
the first centerline sketched as the axis of rotation. The section
must be closed.Options for specifying the angle of
revolution:Variable:Any angle of revolution less than 360 degrees
is specified by using this variable90:Create the feature with a
fixed angle of 90 degrees.180:Create the feature with a fixed angle
of 180 degrees.270:Create the feature with a fixed angle of 270
degrees.360:Create the feature with a fixed angle of 360 degrees.Up
To Point/Vertex:Create the revolved feature up to a point or
vertex. The revolved feature ends when the section plane reaches
the point or vertex.Up to Plane:Create the revolved feature up to
an existing plane or planar surface that must contain the axis of
revolution.
INTRODUCTION TO ANSYS The ANSYS program has many finite element
analysis capabilities, ranging from a simple, linear, static
analysis to a complex non linear, transient dynamic analysis.A
typical ANSYS analysis has three distinct steps: Building the model
Applying loads and obtains the solution Review the results.BUILDING
THE MODEL:Building a finite element model requires a more of an
ANSYS users time than any other part of the analysis. First you
specify the job name and analysis title. Then, define the element
types, real constants, and material properties, and the model
geometry.Defining element types:The analysis element library
contains more than 100 different element types. Each element type
has a unique number and a prefix that identifies the element
category. Example: beam, pipe, plant, shell, solid. Defining
element real constants:Element real constant are the properties
that depend on the element type, such as cross sectional properties
of a beam element. For example real constants for BEAM3 , the 2-d
beam element, or area, moment of inertia(IZZ), height , shear
deflection constant (SHEAR Z), initial strain (ISTRN) different
elements of same type may have different real constant values.
Defining material properties:Most elements types require material
properties. Depending on the application, material properties may
be: Linear or non linear Isotropic, Orthotropic, or an isotropic
Constant temperature or temperature dependantAs with element type
and real constant, each set of material properties has a material
reference number. The table of material reference number verses
material property set ids called material property table. Within,
one analysis you may have multiple material properties set.Material
property test: Although you can define material properties
separately for each element analysis, the ANSY program enables you
to store a material property set in an archival material library
file, then retrieve the set and reuse it in multiple analysis. The
material library files also enable several ANSYS user to share
common used material property data.Overview of model generation:The
ultimate purpose of the finite element analysis is which to
recreate mathematical behavior of an actual engineering system. In
other words, the analysis must be an accurate mathematical model of
a physical prototype. In the broadest sense, this model comprises
all the nodes, elements, material properties, real constant,
boundary conditions, and other features that are used to represent
the physical system. In ANSYS terminology, the term model
generation usually takes on the narrower meaning of generating the
nodes and elements that represent the spatial volume and
connectivity of actual system. Thus, model generation in this
discussion will mean that the process of define the geometric
configuration models nodes and elements.The ANSYS program offers
you the following approaches to model generation: Creating a solid
model within ANSYS. Using direct generation reporting a model
created in CAD system.Meshing your solid model:The procedure for
generating a mesh of nodes & elements consists of three main
steps: Set the element attributes Set mesh controls Generate the
mesh controls,The second step, setting mesh controls, is not always
necessary because the default mesh controls are appropriate for
many models. If no controls are specified, the program will use the
default setting on the de size command to produce a free mesh. As
an alternative, you can use the small size feature to produce a
better quality free mesh.Before meshing the model, and even before
building the model, it is important to think about whether a free
mesh or a mapped mesh is appropriate for the analysis. A free mesh
has no restrictions in terms of element shapes, and has no
specified pattern applied to it.Compared to a free mesh, a mapped
mesh is restricted in terms of the element shape it contains and
the pattern of the mesh. A mapped area mesh contains either only
quadrilateral or only triangular elements, while a mapped volume
mesh contains only hexahedron elements. In addition, a mapped mesh
typically has a regular pattern, with obvious rows of elements. If
you want this type of mesh, you must build the geometry as series
of fairly regular volumes and or areas that can accept a mapped
mesh.Setting element attributes:Before you generate a mesh of nodes
and elements, you must first define the appropriate element
attributes. That is, you must specify the following: Element type
Real constant set Material properties set Element co-ordinate
system. LOADING:The main goal of finite element analysis is to
examine how a structure or component response to certain loading
condition. Specifying the proper loading conditions, therefore, a
key stepping analysis. You can apply loads on the model in variety
of ways in ANSYS program.Loads:The word loads in ANSYS terminology
includes boundary. Conditions and externally or internally applied
forcing functions. Examples of loads in different disciplines are:
Structural: displacement, forces, pressures, temperatures (for
thermal strain), gravity Thermal: temperatures, heat flow rate,
convections, and internal heat generation, infinite surface
Magnetic: Magnetic Potentials, magnetic flux, and magnetic current
segment Electric: electric potentials, electric current, charges,
charge densities, infinite Fluid: Velocities and pressuresA DOF
constraint fixes the degrees of freedom of a known value. Examples
of constraints are specified displacement and symmetric boundary
conditions in structural analysis, prescribed temperatures in
thermal analysis, and flux parallel boundary conditions.A force is
concentrated load applied at a node in a model. Examples are forces
and moments in structural analysis, heat flow rates in thermal
analysis.A surface load is distributed load applied over a surface.
Examples are pressures in structural analysis and convections and
heat fluxes in thermal analysis.Coupled field loads are simple case
of one of the above loads, where results from analysis are used as
loads in another analysis. For examples you may apply magnetic
forces calculated in magnetic field analysis are force loads in
structural analysis. How to apply loads: You can apply loads most
loads either on the solid model (on key points, line, areas) or on
the finite element model (on nodes and elements). For example, you
can specify forces at a key point or a node. Similarly, you can
specify convections (and other surface loads) on lines and areas or
nodes and element faces.No matter how you specify loads, the solver
expects all loads to be in term of finite element model. Therefore
if your specify loads on the solid model, the program automatically
transfers them to the nodes and element at the beginning of the
solution. SOLUTION: In the solution phase of the analysis, the
computer takes over and solves the simultaneous equations that the
finite element method generates. The result of the Solutions are:
nodal degree of freedom values, which form the primary solution,
and b) derived values, which form the element solution. The element
solution is usually calculated at the elements integration points.
The ANSYS program writes the results to the database as well as to
the result file. Several methods of solving the simultaneous
equations are available in the ANSYS program: frontal solution,
sparse direct solution, Jacobi Conjugate gradient (JCG solution,
incomplete cholesky conjugate (ICCG) solution, preconditioned
conjugate gradient (PCG) solution, automatic iterative solver
option (ITER). The frontal solver is the default, but you can
select a different solver.Post processing:After building the model
and obtaining the solution, you will want answers to some critical
question: will the design really work when put to use? How high are
the stresses in this region? How does the temperature of this part
vary with time? What is the heat loss across my model? How does the
magnetic flow through this device? How does the placement of this
object affect fluid flow? The post processors in the ANSYS program
can help you find answer these questions and others.Post processing
means reviewing the results of an analysis. It is probably the most
important step in the analysis, because you are trying to
understand how the applied loads affect your design, how well you
finite element mesh is, and so on. Two post processors are
available review your results: Post 1, the general post processor,
and post 26, the time history post processor. Post 1 allows you to
review the results over the entire model at specific load steps and
sub steps (or at specific time points or frequencies). In a static
structural analysis, for example, you can display the stress
distribution for load step 3 or, in a transient thermal analysis;
you can display the temperature distribution at time 100 seconds.
Result Files:The ANSYS solver writes results of an analysis to the
results file during solution. The name of the results file depends
on the analysis discipline: Job Name.rst for structural analysis.
General Post Processor:You use Post1, the general post processor,
to review analysis results over the entire model, or selected
portion of the model, of a specifically defined combination of
loads at a single time (or frequency). Post 1 has many
capabilities, ranging from simple graphics display and tabular
listing to more complex data manipulation such as load case
combinations.
Displaying Results Graphically:Graphics display is perhaps the
most effective way to review results. You can display the following
types of graphics in post1: Contour displays Deformed shape
displays Vector displays Path plots Reaction force displays
Particle flow traces.INTRODUCTION TO STRUCTURAL ANALYSISStructural
analysis is probably the most common application of the finite
element method. The term structural (or structure) implies not only
civil engineering structures such as bridges and buildings, but
also naval, aeronautical and mechanical structures such as ship
hulls, aircraft bodies and machine housings, as well as mechanical
components such as pistons, machine parts and tools.Types Of
Structural Analysis:The seven types of structural analysis provided
by ANSYS are given below.1. Static analysis: used to determine
displacement, stresses etc. under static loading conditions. Both
linear and non-linear static analyses. Non Linearitys can include
plasticity, stress stiffening, large deflection, large strain,
hyper elasticity, contact surfaces, and creep.2. Modal analysis:
used to calculate the natural frequencies and mode shapes of a
structure. Different mode extraction methods are available. 3.
Harmonic analysis: used to determine the response of a structure to
harmonically time varying loads.4. Transient dynamic analysis: used
to determine the response of a structure to arbitrarily time
varying loads. All non-linearitys mentioned under static analysis
above are allowed. 5. Spectrum analysis: an extension of the model
analysis, used to calculate stress and strain due to response
spectrum or a PSD input (random vibrations). 6. Buckling analysis:
used to calculate the buckling load and determine the buckling mode
shape. Both linear (Eigen value) buckling and non linear buckling
analyses are possible. Explicit dynamic analysis ANSYS provides an
interface to the LS-Dyna explicit finite element programs is used
to calculate fast solution for large deformation dynamics and
complex contact problems. INTRODUCTION TO THERMAL ANALYSISA steady
state thermal analysis calculates the effects of steady thermal
loads on a system or component. Engineer/analysts often perform a
steady state analysis before doing a transient thermal analysis, to
help establish initial conditions. A steady state analysis also can
be the last step of a transient thermal analysis, performed after
all transient effects have diminished. You use steady state thermal
analysis to determine temperatures, thermal gradients, heat flow
rates, and thermal loads that do not vary over time cause heat
fluxes in an object that. Such loads include the following.
Convections Radiations Heat Flow rates Heat fluxes (heat flow per
unit area) Constant temperature boundaries.A steady state thermal
analysis may be either linear, with constant material properties;
or non linear, with material properties that depend on temperature.
The thermal properties of most material do vary with temperature,
so the analysis usually is non linear, including radiation effects
also makes the analysis non linear.FINITE ELEMENT ANALYSISFinite
element analysis (FEA) has become commonplace in recent years, and
is now the basis of a multibillion dollar per year industry.
Numerical solutions to even very complicated stress problems can
now be obtained routinely using FEA, and the method is so important
that even introductory treatments of Mechanics of Materials { such
as these modules { should outline its principal features. In spite
of the great power of FEA, the disadvantages of computer solutions
must be kept inmind when using this and similar methods: they do
not necessarily reveal how the stresses are influenced by important
problem variables such as materials properties and geometrical
features, and errors in input data can produce wildly incorrect
results that may be overlooked by the analyst. Perhaps the most
important function of theoretical modeling is that of sharpening
the designer's intuition; users of finite element codes should plan
their strategy toward this end, supplementing the computer
simulation with as much closed-form and experimental analysis as
possible.Finite element codes are less complicated than many of the
word processing and spreadsheet packages found on modern
microcomputers. Nevertheless, they are complex enough that most
users do to program their own code. A number of prewritten
commercial codes are available, representing a broad price range
and compatible with machines from microcomputers to
supercomputers1. However, users with specialized needs should not
necessarily shy away from code development, and may the code
sources available in such texts as that by Zienkiewicz2 to be a
useful starting point. Most finite element software is written in
FORTRAN, but some newer codes such as felt are in C or other more
modern programming languages.
CONCLUSIONRocker arm is an important component of engine,
failure of rocker arm makes engine useless also requires costly
procurement and replacement. An extensive research in the past
clearly indicates that the problem has not yet been overcome
completely and designers are facing lot of problems specially,
stress concentration and effect of loading and other factors. The
finite element method is the most popular approach and found
commonly used for analyzing fracture mechanics problems.Lightweight
rocker arms are a plus for high rpm applications, but strength is
also essential to prevent failure. In recent years, aftermarket
steel roller tip rockers have become a popular upgrade for the most
demanding racing applications. Some of these steel rockers are
nearly as light as aluminium rockers. But their main advantage is
that steel has better fatigue strength and stiffness than
aluminium. So we can say that steel is the better material in terms
of strength and aluminium is good for making low cost rocker
arms.
The design of the project was successfully completed using
pro/E. The problems which emerged during the design of the machine
where successfully over come using PRO/E .The design of the project
involved making use of most of the important features of pro/E is
versatile and comprehensive software foe three-dimensional solid
modeling.Protrusion and cut are used as main feature to develop the
components. The components are drawn very using PRO/E.
PHTOGRAPHY
ANALYSIS PICTURECAD Model of Rocker Arm
Reaction Force Acting at the Pin
Equivalent Stress
Maximum Shear Stress
Force Acting at the ExhaustValve End of Rocker Arm
Equivalent Stress
Maximum Shear Stress
BIBLIOGRAPHY1. PTC Series Manual for Pro-E.1. Machine Drawing by
K.R.Gopalakrishna1. CAD/CAM by Groover.1. Www. PTC. COM1. Www.
Mech.nwu.edu/ Pro-E /toc.htmWebsite:1. www.Ansys.com
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