We were discussing the basic concept of streamline and equipotential line, dimensional homogeneity, Buckingham pi theorem and difference between model and prototype
in the subject of fluid mechanics, in our recent posts.
Now we will go ahead to understand the basic
principle of similitude i.e. types of similarity in the field of fluid
mechanics with the help of this post.
Let us have a brief look over the basics of model
and prototypes
In order to secure the information about the
performance of any hydraulic structure such as dam or any hydraulic machine
such as turbine, before going for construction and manufacturing of actual of
structure or machine, models are prepared of the actual structure or machine
and experiments are carried out on the models to secure the desired result.
Therefore we can define the model as the small scale
replica of the actual structure or machine. Actual structure or machine will be
termed as prototype.
Similitude – Types of similarities
Similitude is basically defined as the similarity
between model and its prototype in each and every respect. It suggests us that
model and prototype will have similar properties or we can say that similitude
explains that model and prototype will be completely similar.
Three types of similarities must exist between model
and prototype and these similarities are as mentioned here.
Geometric similarity
Kinemtaic similarity
Dynamic similarity
We will discuss each type of similarity one by one
in detail. Let us first see here geometric similarity.
Geometric similarity
Geometric similarity is the similarity of shape.
Geometric similarity is said to exist between model and prototype, if the ratio
of all respective linear dimension in model and prototype are equal.
Ratio of dimension of model and corresponding
dimension of prototype will be termed as scale ratio i.e. Lr.
Let us assume the following linear dimension in
model and prototype.
Lm = Length of model, LP = Length of
prototype
Bm = Breadth of model, BP =
Breadth prototype
Dm = Diameter of model, DP =
Diameter of prototype
Am = Area of model, AP = Area
of prototype
Vm = Volume of model, VP =
Volume of prototype
Kinematic Similarity
The Kinemetic similarity is said to exist between
model and prototype, if the ratios of velocity and acceleration at a point in
model and at the respective point in the prototype are the same.
We must note it here that the direction of velocity
and acceleration in the model and prototype must be identical.
Vm = Velocity of fluid at a point in
model, VP = Velocity of fluid at respective point in prototype
am = Acceleration of fluid at a point in
model, aP = Acceleration of fluid at respective point in prototype
Dynamic Similarity
The dynamic similarity is said to exist between
model and prototype, if the ratios of corresponding forces acting at the
corresponding points are the same.
We must note it here that the direction of forces at
the corresponding points in the model and prototype must be same.
Fm = Force at a point in model, FP =
Force at respective point in prototype
We will see another important topic
in the field of fluid mechanics i.e. Types of forces acting in moving
fluid with the help of our next post.
Do you have any suggestions? Please write in comment
box.
Reference:
Fluid mechanics, By R. K. Bansal
Image Courtesy: GoogleÂ
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