Pharmaceutical Technology I Lecture 1 Drying PDF

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This document presents a lecture on drying methods in pharmaceutical technology. It discusses various drying techniques, their advantages, disadvantages, and application examples.

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Pharmaceutical
Technology I
Lecture 1
Prof. Omaima Sammour
Professor of Pharmaceutics &
Industrial Pharmacy
Prof. Omaima Sammour
 Drying is an important operation involved
 in primary stage of manufacturing (i.e. the
synthesis of actives) and in the last stage of
manufacturing (before packaging)

The residual moisture content of a
pharmaceutical product should be low
enough to:
a. Prevent product deterioration during storage
b. Ensure free-flowing properties during use
 Drying to the solid state may start with either
a wet solid or a solution or a suspension
of the material
Prof. Omaima Sammour
Prof. Omaima Sammour
 Total moisture content of a wet solid:
Is the total amount of liquid associated with
a wet solid
Not all of it can be easily removed by
pharmaceutical driers
The easily removable water is known as the
“free moisture content” or “unbound water”
The moisture which is more difficult to
remove is the equilibrium moisture content
because the solid equilibrates with the
moisture present in the air
Prof. Omaima Sammour
 Equilibrium moisture content:

Is the moisture content present in a solid
under ambient conditions
its value changes with:
a. temperature
b. humidity
c. the nature of the solid
It may be adsorbed on surfaces of the solid (to
form a mono- or bi-layer on the solid surface)
or impeded within its structure
Prof. Omaima Sammour
 Types of Drying Methods
When considering how to dry a material, the
following points should be considered:
1. Heat sensitivity of the material being dried
2. Physical characteristics of the material
3. Nature of the liquid to be removed
4. The scale of operation
5. Available sources of heat

Prof. Omaima Sammour
 General principles for efficient drying
1. Large surface area for heat transfer
2. Efficient heat transfer per unit area to apply
sufficient latent heat of vaporization or heat of
sublimation (in case of freeze drying)
3. Efficient mass transfer of evaporated water
through any surrounding boundary layers
4. Sufficient turbulence to minimize boundary layer
thickness
5. Efficient vapor removal
i.e. low relative humidity of air at adequate velocity
Prof. Omaima Sammour
 It is convenient to categorize
Pharmaceutical driers according to
the heat transfer method they use
Into:

Convective Radiant
Conductive

Prof. Omaima Sammour
 A) Convective Drying of Wet Solids
1) Fixed (static) bed convective driers
e.g. Tray (or shelf) Drier (Batch Drier)
Air flows in the direction of the arrows over each shelf in turn
The wet material is spread on shallow trays resting on the
shelves
Electrical elements or steam-heated pipes are positioned as
shown, so that the air is periodically reheated after it has
cooled by passage over the wet material on one shelf before it
passes over the material on the next

Prof. Omaima Sammour
Rate of drying in fixed beds:
The rate at which drying occurs has been found to
show certain phases, in which the change in
moisture content is plotted against time

Prof. Omaima Sammour
1- From A – B:
the relationship is linear (constant-rate period)
for given conditions of temp & humidity, most substances
dry at a similar rate in the constant rate period
The evaporation takes place from the wet surface of the
solid & the surface remains wet in this period as a result of
the liquid being replaced from below as fast as it is
vaporized
The end of the constant rate period B is referred to as
“critical moisture content”

Prof. Omaima Sammour
2- From B – C:
The rate of loss of moisture decreases & is known as
“the falling rate period”

1st falling rate period 2nd falling rate period
Linear relationship there is a continuous
i.e. the decrease in decrease in the drying
drying rate is uniform rate until equilibrium
moisture content is
reached
as the drying rate decreases, the heat input should be
reduced Prof. Omaima Sammour
 During the FFRP, the rate of drying falls
steeply due to the drying of surface granules
 The SFRP is influenced by the diffusion of
moisture through the pores of the bed to the
surface i.e, the plane of vaporization retreats
from the surface into the body of the solid &
 Applications of Tray drier:
Useful for sticky or plastic substances, granular
masses, pastes & precipitates
Prof. Omaima Sammour
 Advantages
1. Material loss is negligible since loading &
unloading of trays can be handled carefully →
hence, this dryer is very useful for valuable
materials
2. It is a batch operation hence, useful when
the material is available in small quantities
3. With the exception of dusty solids, materials
of almost any physical form may be used

Prof. Omaima Sammour
 Disadvantages
1. Oxidisable & thermolabile materials can’t
be dried
2. It takes a long time to dry, as the material is
static
3. Labour requirements are high for loading &
unloading operations
4. A long heating cycle is necessary for
internal diffusion of heat or moisture

Prof. Omaima Sammour
5. A large floor space is required for the oven &
for tray loading facilities
6. Solvents are difficult to recover from the
drying air
7. Moisture movement may cause the
migration of soluble drugs or excipients

 It is used in such cases where the quantity
of material to be processed doesn’t justify
investment in more expensive continuous
equipment
Prof. Omaima Sammour
 2) Dynamic Convective Driers
e.g. Fluidized – Bed Drier

It is an excellent method of obtaining good
contact between the warm drying air & wet
particles
Such units have replaced tray dryers in
many processes

Prof. Omaima Sammour
 Sizes are available with capacities from 1kg
in the laboratory to 500kg in production

 These driers can be operated batch-wise
(batch fluidized bed drier):

 A charge of wet solids ( granular, non
sticky, free flowing) in a perforated
container attached to the bottom of the
fluidizing chamber is fluidized by a
stream of heated air (gas) until dry &
then discharged (loading & unloading)

 particles between 65mm - 10µm are the
best for smooth fluidization (A mix of
fine particles to coarse ones results in
better fluidization)

Prof. Omaima Sammour
 Economic considerations make fluidized bed
dryers attractive when large amounts of solids
are to be handled
i.e. in this case a “continuous dryer” is more
suitable than a batch type

 The fluidized bed dryer is also used as a
classifier so that both drying & classification
operations are accomplished simultaneously

They can also be used for size enlargement &
coating of materials
Prof. Omaima Sammour
 Advantages of fluidized-bed drying
1. Efficient heat & mass transfer gives high
drying rates, so that drying times are
shorter than with static-bed convection
drier
e.g. A batch of tablet granules can be dried in
20 – 30 min whereas a tray drier requires
many hrs Apart from the economic
advantage, the heat challenge to
thermolabile materials is minimized

Prof. Omaima Sammour
2. The fluidized state of the bed ensures that
drying occurs from the surface of all individual
particles & not just from the surface of the bed

3. The temperature of a fluidized bed is uniform
& can be controlled precisely

4. The turbulence in a fluidized bed causes some
attrition to the surface of the granule more
spherical free-flowing product

Prof. Omaima Sammour
5. The free movement of individual particles
eliminates the risk of soluble materials’
intergranular migration

6. The containers can be mobile simple
handling & movement around the production
area

7. Short drying times high output

Prof. Omaima Sammour
 Disadvantages
1. The turbulence of the fluidized state excessive
attrition of some materials damage to some
granules production of too much dust

2. Fine particles may become entrained in the
fluidizing air and must be collected by bag filters
with care to avoid segregation & loss of fines

3. The vigorous movement of particles in hot dry air
can lead to the generation of static electricity
charges, so adequate electrical earthing may be
essential Prof. Omaima Sammour
 B) Conductive Drying of Wet Solids

In this process, the wet solid is in thermal
contact with a hot surface the bulk of
heat transfer occurs by conduction

Examples:
1. Vacuum oven
2. Vacuum tumbling drier

Prof. Omaima Sammour
1- Vacuum Oven (Batch)

Prof. Omaima Sammour
 It consists of a jacketed vessel which can
withstand vacuum within the oven & steam
pressure in the jacket
The supports for the shelves form part of the
jacket, giving a larger area for conduction
heat transfer
Heat is supplied by passing steam or hot
water through these hollow shelves, upon
which the material may be placed in suitable
trays
Prof. Omaima Sammour
 The steam or water heats the material → water
evaporation under reduced pressure → water
condensation in the condenser
The oven can be closed by a door that can be
locked to give an air tight seal
Drying times are long (12 – 48 hrs)
Rarely used nowadays for production, but are
frequently used in development laboratories for
drying small samples
 Advantages:
1- Drying takes place at low temp → used for
thermolabile substances
2- There is little air present → minimum risk of
oxidation Prof. Omaima Sammour
 2- Vacuum Tumbling Drier (Batch)
It has found application in the
pharmaceutical industry
It resembles a large V/Y-cone
mixer or double cone mixer →
the vessel is steam jacketed &
connected to a vacuum
Is used for drying tablet
granules, which tumble over
the heated surface as the
vessel slowly revolves
Heat transfer rate > that
attained in vacuum oven
(where the material is static)
Drying times: 2 – 3.5 hrs
Prof. Omaima Sammour
 C) Radiation Drying of Wet Solids)

Heat transmission by radiation differs from
heat transfer by conduction or convection, in
that no transfer medium (solid, liquid or gas)
needs to be present

Heat energy in the form of radiation can travel
through the atmosphere without loss If it
falls on a body capable of absorbing it, it
appears as heat although a proportion may be
reflected or transmitted
Prof. Omaima Sammour
Use of infrared radiation:
IR heating has been used in the past to dry
wet granules, but it suffers from the
disadvantage of being absorbed very quickly
without penetrating far into the wet mass

Therefore, it is now seldom used as a heat
source in pharmaceutical manufacture

Prof. Omaima Sammour
 Use of microwave radiation:
Microwave radiation (wavelength range 10mm –
1m) penetrates much better than IR radiation
Microwaves are produced by an electronic
device known as a Magnetron
The penetration of microwaves into the wet
product is so good that heat is generated
uniformly within the solid → moisture
evaporation
It is used for drying granules

Prof. Omaima Sammour
 Advantages of microwave drying
1. Provides rapid drying at fairly low temp.
2. Most microwave energy is absorbed by the
liquid in the wet material
3. The bed is stationary, avoiding the problems of
dust & attrition
4. Solute migration is reduced as there is uniform
heating of the wet mass
5. All the requirements of product & operator
safety have been incorporated into machines
without detracting from GMP considerations
Prof. Omaima Sammour
 Disadvantages of microwave drying
1. The batch size of commercial production
microwave driers is smaller than those
available for fluidized-bed driers
2. Care must be taken to shield operators from
the microwave radiation, which can cause
damage to organs such as the eyes & testes
This is ensured by “fail safe” devices, which
prevent the generation of microwaves until the
drying chamber is sealed

Prof. Omaima Sammour