Manufacturing and Processing Technology in Food PDF

Summary

This document covers manufacturing and processing technology in the food sector, focusing on the essential utilities required in various industrial settings. It details various water systems, grades of water relevant for processing, the impurities present in water, purification methods, and specific testing processes. The document provides a comprehensive overview of topics.

Full Transcript

Manufacturing and Processing Technology
in
Food
 Learning Objectives

 At the end of this section the student should
understand
 The grades of water
 The uses of water
 The impurities present
 The Purification Methods
 The tests to check purity
 The other essential Process Utility Systems
necessary to support a facility
Manufacturing & Processing Technology -
Utilities

3
 Utilities

 Utilities are the process supplements of an industrial plant as
power, steam or water.
 The most common sources of energy are oil, gas, coal and nuclear
energy. The decreasing availability of some sources will
necessitate the use of alternative forms of energy.
 In the production industry the required power is primarily in the
form of electricity, other sources are steam engines, internal-
combustion engines and hydraulic turbines.
 When a design engineer is setting up the specifications for a
new plant, a decision must be based on whether to use purchased
power or producing its own power. (if both exist continuous
operation is achieved)
 The quantity of steam used in a process varies depending on
thermal and mechanical requirements and should be generated
from whatever fuel is cheapest.
 Water Systems
 Grades and Uses of water
 Impurities in Water
 Testing of Water
 Purification Systems

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 Water Systems

Grades and uses of water

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 Grades of Water

 There are three main grades of water used in
manufacturing plants.
 Each grade has been treated using some technique

 Water types include:
Potable Water
Purified Water
Water for Injection (WFI)

 Different processes in manufacturing plants require
different purities of water.

 The water used for each process is specified in the Batch
Production Record (BPR).
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 Grades of Water - Potable Water

 Types of Water –

 Potable water is low grade water and is usually
supplied by the municipal water system. Typical uses
for potable water are for drinking, plumbing and fire
fighting.
 The main use for potable water in a plant is to
produce purified water and WFI.
 Potable water must be purified by a number of
treatment processes before it can be used in
manufacturing.

8
 Grades of Water- Purified Water

 Purified water is potable water that has been subjected to
further purification by either distillation, deionization or
reverse osmosis.

9
 Grades of Water- Water for Injection

 Water for injection (WFI) is used for the
manufacture of sterile products.

 This requires the water to be virtually free from
any microbial contamination
 This makes WFI more difficult to produce than
purified
water
 WFI has the same chemical specifications as
purified water but has extra microbial
requirements

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 Grades of Water

 Water for injection must comply with the following tests
 clarity and color of solution
 acidity and alkalinity
 oxidisable substances
 non-volatile matter
 pyrogens
 bioburden limits

 All aqueous injections should be prepared with WFI

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Water Systems

Water Impurities

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 Water Impurities &Treatment

Water is widely used in a plant.
 It is used for cleaning equipment and also in
processing.
 Water coming into a plant is normally impure and
must be treated before it can be used.
Water coming directly into a plant from the local water
supply contains impurities.

1
 Common water impurities

Common water impurities include:

 Particulates

 Colloids

 Ions

Organics

 Micro-organisms 14
 Common water impurities - Particulates

Particulates are undissolved solid materials that are in water.

These undissolved particles could be dirt, soil or dust depending
on where the water has come from.

An initial filtration process for example will remove the majority
of particulate matter.

It is important that the particulates are removed because they
are a source of contamination

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 Common water impurities - Colloids

Colloids are very small undissolved materials.
 They are similar to particulates but they remain
suspended in the water.
 Colloids are too small to be seen by the naked eye.
 They can be detected by shining light, which will be
reflected by the small particles, on a water sample.
 This reflection effect is called the Tyndall effect.
 Colloids must be removed from the water, as they are
a source of contamination in reaction processes.

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 Common water impurities - Ions

Ions are charged materials, dissolved in water.
If a water sample has a high ion concentration, it is usually an
indication that the water has a high metal content.

Metals, such as lead, can have harmful side-effects to humans.
They are not broken down by the body and therefore can
accumulate in the body’s tissue.

Unwanted ions, present in water, can also affect the manufacturing
process and lead to impurities being present in the final API.

Calcium and magnesium are metal ions, which if present in high
concentrations in water cause a condition called “hard water”.
 If these ions are not removed the hard water will cause scale
formation on equipment and could block pipelines.
1
 Common water impurities - Organic
Contaminants

Organic contaminants are classified as any
material that contains carbon. Typical organics could
include pesticides or food residues.

Usually all organic material is removed by the local
treatment facility.

The presence of organic contamination creates a food
source for bacteria to multiply and therefore increases
the risk of microbial contamination of the final
product.

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 Common water impurities – Micro-organisms

Micro-organisms
are the smallest of all living organisms, which can only be
seen clearly under a microscope.

Micro-organisms are found in all domestic water supplies.

The quantity and types of micro-organisms must be controlled
before the water can be used in some plants.

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 Common water impurities – Micro-organisms

If the contaminated water is used in a processing
step, the micro-organisms could end up in the final
product. This can have serious implications for the
patient.

Micro-organisms must be removed or reduced to a
specific safe level, before they can be used in the
process.

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Water Systems

Water Testing

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 Water Testing

 After the plant water has been treated, it must be sampled
and tested to ensure it meets the correct quality
specifications.
 The main checks and tests that an operator could perform
are:
 Conductivity
 pH
 Other important tests carried out by the laboratory include:
 Bacterial Counts
 Total Organic Carbon (TOC)
 Heavy Metals
 Endotoxin
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 Nitrates
 Water Testing

Conductivity is a measure of the quantity of ions in a water
sample.

If the conductivity of the water is very high this indicates a
quality problem with the water, which is usually caused by the
presence of ions such as calcium and magnesium.

The conductivity is measured by a conductivity probe within
the water storage vessel or alternatively a portable
conductivity meter can measure small samples taken from the
vessel.

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 Water Testing

pH is a measure of how acidic or basic the water is. Normally
the pH should be between 5 and 7 for purified water.

Any pH readings outside the expected range will indicate a
possible contamination of the water.

Low pH readings mean that the water is acidic and high pH
readings mean that it is basic.

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 Water Testing

 Total organic carbon (TOC) is a measure of
the total organic content in a water sample.
 Pure water has a low TOC reading as it will
contain very little organic material and impure
 Impure water has a high TOC reading.
 If the TOC readings are outside the specified
range, it means that the water has organic
contaminants present.

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Water Systems

Water Purification

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 Water Treatment

 Typical treatment processes include:
 Particulate Filtration
 Carbon Filtration
 Reverse Osmosis
Purified Water Generation
 Water Softening
 Ion Exchange Resins
 Ultraviolet (UV) Light
 Distillation WFI Generation

 Circulation

27
 Water Treatment - Filtration

Filtration is an important process that removes
insoluble solids from a liquid.
The water coming into the plant is normally filtered to
remove the initial undissolved material, before any
specific treatment procedures are carried out.
There are also special filters which are designed to
remove micro-organisms and colloids. These have a
much smaller filter size and are capable of retaining
much smaller particles.

Removes contaminants 10 – 20 microns in size

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 Water Treatment - Filtration

Another form of filtration, activated carbon filtration, is used to
remove organic material and residual disinfectant from water.

Chlorine is the most commonly used water disinfectant. Residual
levels of it are often present in water entering the plant. It is
important to remove residual disinfectant because it can reduce
the effectiveness of subsequent treatment techniques.

29
 Water Treatment - Ion Exchange Resins

 Ion exchange resins are specifically designed
to remove ions from water.

 An ion is any material that has either a positive
or negative charge.
 For example Ca2+ is a positively charged ion
and SO42- is a negatively charged ion.

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 Water Treatment - Ion Exchange
Resins

 The water is passed through an ion exchange unit that
contains the resin.

 The resin will absorb the ions thus removing them from
the water.

 Resins become saturated after prolonged usage and
have to be regenerated with a chemical treatment
process, on a regular basis, so they continue to work
effectively.

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 Water Treatment - Reverse Osmosis

 Reverse osmosis is a technique used to remove
ions and other dissolved contaminants from water.

 The water to be purified is forced through a
semipermeable membrane using pressure.
 The membrane retains ions and other dissolved
contaminants but allows the pure water molecules to
pass through.

32
 Water Treatment - Ultraviolet Light

 Ultraviolet light is a form of energy that can be
generated by mercury lamps.

 The energy or radiation given off by the lamps passes
through a water solution and destroys most of the
bacteria in the water.

 The UV light is absorbed by the cells of the bacteria,
killing them.

33
 Water Treatment - Distillation

Distillation is a simple method for removing
impurities from water. The in-coming water is
heated.

When the temperature of the water reaches the
boiling point, vapor is formed.
 This vapor leaves the vessel, leaving the impurities
behind and is transferred to the condenser.

The condenser cools the vapor back into water,
which is then collected separately in a holding
vessel. 34
 Water Treatment - Distillation

It is also important, once the water has been
treated, that it is kept moving by
 circulating it within a system. This reduces the risk
of bacterial contamination, as stagnant water is a
breeding ground for micro-organisms.
Certain grades of water are stored at 80oC,
which reduces the risk of microbiological
contamination before use.

35
Manufacturing & Processing
Technology
Plant Utilities

36
 Plant Utilities

 Compressed Air
 Steam
 Gases
 Water
 HVAC

37
 Process Utility Systems (PUS)

 Manufacturing Plants need a wide range of utilities in order to manufacture their
products.

 Process utility systems (PUS) are required to satisfy the demands of the facility in such
areas as:
 Compressed Air
 Steam
 Vacuum
 Electricity
 Gases
 Water
 Effluent Disposal System
 Heating, Ventilation and air conditioning system (HVAC)
 Extraction System

38
Plant Utilities

Compressed Air

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 3 Categories of Compressed Air

 Process Air - oil free, dry, particle free and
suitable after terminal filtration for product
contact

 Plant Instrument Air - Dry, particle free and
suitable for pneumatic equipment

 Breathing Air - as process air but HEPA
filtered
40
 Compressed Air

 An example of the type of equipment used to create
compressed air is a rotary type air-compressor. The
rotary compressor is one of the most popular source
of compressed air for industrial applications.
 Operation: Air enters a sealed chamber where it is
trapped between two rotating rotors. As the rotors
intermesh, they reduce the volume of trapped air and
deliver it compressed to the proper pressure level.
Example of compressor
rotors

41
 Compressed Air

 Compressed Air can be used at different pressures depending
upon the application.

 Plant Instrument air being used to drive valves and general
equipment is generally used at approximately 6 barg.

 Process air being introduced to vessels is generally used at a
pressure less than 3 barg.

 The pressure of the air is regulated using a pressure reducing
valve.

42
Plant Utilities

Steam

43
 Steam

 Steam is generally piped around the plant from a central boiler.
The main use is for heating. It is also used in the generation of
Clean Steam which in turn is used for sterilization purposes.

 Steam can be produced at different pressures, at each
different pressure, the steam will have a corresponding
temperature value. Therefore the pressure of steam produced
will be dependent on temperature requirements.

 Typically the steam pressure used within the plant would be
approx. 3 barg again this is controlled by a pressure reducing
valve.

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 Steam

 Diagram of a Typical Steam Boiler

Recovered
Hot Flue Fresh Condensat
Plant Steam Gases water e
Plant Water makeup

Gas Condensate
Recovery
Tank

Air Burne
r

Fire Tubes
Plant Water In

45
 Clean Steam

 Clean Steam is used primarily for sterilisation sequences, for
example loop sterilisation and sterilisation of vessels.

 Clean Steam is a high purity steam produced from treated water
for example De-Ionised water/ Water for Injection (WFI). It is
therefore used instead of normal steam for sanitary applications
to reduce the incidence of cross contamination.

 Clean steam is usually utilised at a lower pressure and hence lower
temperature than normal steam. As the main purpose is for
sterilisation temperatures only need exceed the sterilisation
temperatures i.e 121°C.

46
 Clean Steam

 The production of clean steam is similar to the process for
creating normal steam as described previously. The difference
in this case is that the normal steam is now the heating medium
and purified water or WFI is the medium that is being
converted to steam.
Pressure
Clean Steam To Plant Vessel
 Example of a clean steam generator:

Inlet De-
Normal Ionised
Steam Water

Condensate Tube Bundle
Out De-Ionised
47 Water In
Plant Utilities

Gases

48
 Gases

 Gases are used for a wide range of applications including
 heating fuel
 inert atmospheres to protect product from oxidation
 purging of vessels and pipelines
 operation of laboratory equipment etc.

49
 Plant Utilities

Electricity
Vacuum
Effluent Disposal System
Ventilation systems

50
 Electricity and Vacuum

 Electricity
 generally supplied from the national electricity supplier and is
used for lighting and equipment power. Some plants have back up
generators to cover power failures. Electricity is used throughout
the plant for most pieces of equipment.

 Vacuum
 used for dust extraction and autoclave vacuum. It is supplied
locally from a vacuum pump or from a system which is piped
around the plant from a central vacuum pump.

51
 Effluent Disposal & Ventilation

 Effluent disposal systems
 crucial on all manufacturing sites and are the focus of environmental regulations.
Safe disposal of waste products and spillages

 Ventilation systems
 provide safe working atmospheres, prevention of contamination,maintenance of
specific working conditions, provide adequate supply of air at the right quality.
 Air supplied in sterile areas are absolutely crucial in ensuring product quality.
Typically each building on a site will have its own ventilation system.

 Extraction systems
 important for both environmental control and protection of operators
 remove dust or fumes from the local workplace
 clean or filter the extract before discharging into the environment

52
 Effluent Disposal

 Example of a simple effluent disposal system

53
Plant Utilities

HVAC

54
 Heating, Ventilation and Air Conditioning
(HVAC)

 Production areas should be effectively ventilated, with air
control facilities appropriate to both the products handled, to
the operations undertaken and to the external environment

 Temperature, humidity and Ventilation should be appropriate so
as they do not adversely affect the medicinal products during
their manufacture and storage

55
 Summary

 This section reviewed typical process utility systems

56
 Learning Objectives

 At the end of this section the student should now
understand
 The grades of water
 The uses of water
 The impurities present in water
 The Purification Methods for water
 The tests to check purity of water
 The other essential Process Utility Systems necessary
to support a facility