Mixing part 1

Industrial pharmacy
Lec 1:
mixing
Pharmacist
Hussein kadhim alkufi
MSc in pharmaceutics
Collage of thi-qar
University of pharmacy

Mixing
is a process in which two or more components in a
separate or roughly mixed condition are treated so that
each particle lies as nearly as possible in contact with a
particle of each of the other ingredients.
Purposes of pharmaceutical mixing
• To ensure even distribution of the API
• To ensure even appearance
• To ensure the release of the drug at the correct site
and at the desired rate

Generally mixing is carried out to obtain
following type of products:
• When two or more than two miscible liquids
are mixed together, this results in to a solution
known as true solution.
• When two immiscible liquids are mixed in the
presence of an emulsifying agent, an emulsion
is produced.

• When a solid is dissolved in a vehicle, a solution
is obtained
• When an insoluble solid is mixed with a vehicle,
a suspension is obtained.
• When a solid or liquid is mixed with a semisolid
base, an ointment or a suppository is
produced.

• When two or more than two solid substances
are mixed together, a powder is obtained which
when filled into capsule shell is known as
capsules and when compressed under heavy
pressure is called tablet.

Types of Mixtures
Mixtures may be classified as follows:
1. Positive mixtures
2. Negative mixtures
3. Neutral mixtures

Positive Mixtures
These types of mixtures are formed when two
or more than two gases or miscible liquids are
mixed together by means of diffusion process. In
this case no energy is required provided the
time allowed for solution formation is sufficient.
These types of materials do not create any
problem in mixing.

Negative mixtures
These types of mixtures are formed when
insoluble solids are mixed with a vehicle to form
a suspension or when two immiscible liquids are
mixed to form an emulsion. These mixtures are
more difficult to prepare and require a higher
degree of mixing with external force as there is
tendency of the components of these mixtures
separate out unless they are continuously
stirred.

Neutral mixtures
• Many pharmaceutical products such as pastes,
ointments and mixed powders are the
examples of neutral mixtures. They are static
in their behavior. The components of such
products do not have any tendency to mix
spontaneously but once mixed, they do not
separate out easily.

Fluid mixing
Fluid may generally be classified as newtonian
or non-newtonian depending on the
relationship between their shear rates and the
applied stress.
Compare between newtonian and non-
newtonian system????

Mechanisms of Mixing for Liquids
Mixing mechanisms for fluids fall essentially into
four categories: bulk transport, turbulent flow,
laminar flow, and molecular diffusion.
Usually more than one of these processes is
operative in practical mixing situations.

Bulk transport
the movement of a relatively large portion of the
material being mixed from one location in the system
to another constitutes bulk transport.
A simple circulation of material in a mixer may not
necessarily result in efficient mixing.

For bulk transport to be effective it must result in a
rearrangement or permutation of the various
portions of the material to be mixed.
This can be accomplished by means of paddles,
revolving blades, or other devices within the mixer
arranged so as to move adjacent volumes of the
fluid in different directions, thereby shuffling the
system in three dimensions.

Turbulent Mixing
the phenomenon of turbulent mixing is a direct
result of turbulent fluid flow, which is characterized
by a random fluctuation of the fluid velocity at any
given point with in the system. The fluid velocity at
a given instant may be expressed as the vector sum
of its components in the x, y, and z directions.

• Turbulent flow can be conveniently visualized
as a composite of eddies of various sizes. An
eddy is defined as a portion of fluid moving as
a unit in a direction often contrary to that of
the general flow.
• Large eddies tend to break up; forming eddies
of smaller and smaller sizes until they are no
longer distinguishable.
• The size distribution of eddies within a
turbulent region is referred to as the scale of
turbulence.

Laminar mixing
Streamline or laminar flow is frequently encountered
when highly viscous liquids are being processed.
It can also occur if stirring is relatively gentle and
may exist adjacent to stationary surfaces in vessels in
which the flow is predominantly turbulent.

When two dissimilar liquids are mixed through
laminar flow, the shear that is generated
stretches the interface between them.
If the mixer employed folds the layers back upon
themselves, the number of layers, and hence the
interfacial area between them, increase
exponentially with time.

Molecular diffusion
The primary mechanism responsible for mixing at the
molecular level is diffusion resulting from the
thermal motion of the molecules.
When it comes in conjunction with laminar flow,
molecular diffusion tends to reduce the sharp
discontinuities at the interface between the fluid
layers, and if allowed to proceed for sufficient time,
results in complete mixing.

The process is described quantitatively in terms of
Fick’s law of diffusion:
Where, the rate of transport of mass, dm/dt
across an interface of area A is proportional to the
concentration gradient, dc/dx, across the
interface.
Dm/dt = -DA dc/dx

The rate of intermingling is governed also by the
diffusion coefficient, D, which is a function of
variables including fluid viscosity and size of the
diffusing molecules.

Equipment
 Batch mixing
 Continuous mixing

Batch mixing
When the material to be mixed is limited in volume
to that which may be conveniently contained in a
suitable mixer, batch mixing is usually most feasible.
A system for batch mixing commonly consists of
two primary components
1. Tank or other container suitable to hold the
material being mixed
2. A mean of supplying energy to the system so as
to bring about reasonably rapid mixing

Power may be supplied to the fluid mass by
means of an
1_Impeller
2_Air stream
3_Liquid jet

Impeller
• The distinction between impeller types is often
made on the basis of type of flow pattern the
produce, or on the basis of the shape and pitch of
the blades.
• Three basic types of flow may be produced: radial,
axial, and tangential. These may occur in singly or in
various combinations. Propellers characteristically
produce flow parallel to their axes of rotation,
whereas turbines may produce either axial or
tangential flow or a combination of these.
Compare between propellers and turbines?????

Continuous mixing
The process of contain upon mixing produces an
uninterrupted supply of fresh mixed material and is
often desired when very large volumes of material
are to be handled. It can be accomplished essentially
in two ways:
in a tube or pipe through which the material flows
and in which there is very little back flow or
recirculation.
chamber in which a considerable amount of holdup
and circulation occur

Note 1:
To ensure good mixing efficiency, such devices
as vane, baffles, screws, grids, or combination of
these are placed in the mixing tube.

Note 2:
Mixing takes place mainly through mass transport in
direction normal to that of the primary flow.
Note 3:
Mixing in such system requires the careful control of
the feed rate of raw material if a mixture of uniform
composition is to be obtained.
Note 3
in continuous mixing, the equipment of the tank type
is preferred

Note 4
Turbine agitated tank having vertical sidewall baffles.
If the turbine impeller is located near the middle of
the tank, two regions of mixing occur above and
below the impeller.

Mixing part 1

More Related Content

What's hot (20)

Similar to Mixing part 1 (20)

More from Hussein Alkufi (7)

Recently uploaded (20)

Mixing part 1