Mixing

8

ICHAPTER

".

Selected Definitions

'\fixing: It is defined as a process in which two or more components within a system are converted into one mass or mixture. Ideal Mixing: It is the process in which different materials are thoroughly combined to produce homogenous product. I (I~itive Mixtures:

These are prepared by mixing two miscible liquids.

I IÂŤ'~ative

Mixtures: These mixtures are prepared by mixing insoluble solids in a vehicle in case of suspension or by mixing two immiscible liquids in case of emulsion. 'trat Mixtures: Some products such as Pastes, ointments etc do not mix spontaneously but after mixing they do not separate out easily. , wectlve Mixing: These are the mixing in which the groups of particles move from one position to another. It is also referred to as macromixing.

"hear Mixing: In this mixing, shearing forces are created within the mass of the material by the use of a stirring arm or a burst of air. iffusive Mixing: During this mixing, gravitational forces cause the upper layers of materials to slip and random motion of the individual particles takes place on newly developed surfaces. This is also sometimes known as micromixing. ~ible liquids: These liquids mix with each other in all proportion. !' ,.

i lIy miscible liquids: These liquids mix with each other at specific proportion.

mtiscible liquids: They are not miscible. , transport:

It is the movement of large portion of material from one location to another location.

¡'ulent Mixing: In this, mixing is due to turbulence. Turbulence is a function of velocity gradient between two adjacent layers of a liquid . . mar Mixing I Streamline Mixing: This type of mixing occur when two dissimilar liquids are mixed through a laminar flow, the shear that is generated stretches the interface between them. ular Diffusion: molecules.

It is mixing at the molecular level is the diffusion resulting from the thermal movement of the

I rs: These are mechanical device that are used to mix liquid materials by using blades. '" enizer; They are used to convert coarse emulsion to flne emulsion.

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8.1 INTRODUCTION Mixing is defined as a process in which two or more components within a system mass or mixture. Ideal Mixing indicates that different materials are thoroughly homogenous product. Random Mixingis probability of finding same proportions of mixture. Ordered Mixing yields the closest situation of the perfect mix and it mechanical, adhesion or coating force.

(a)

are converted into one combined to produce component in the entire is achieved by use of

(b)

Figure 8.1: (a) Ideal Mixing (b) Random Mixing The term Mixing and Blending are often used interchangeably Blending means to mix or intermingle smoothly or inseparably.

but technically they are slight different.

8.2 TYPES OF MIXTURES Mixtures can be classified as a.

Positive Mixtures: These are prepared by mixing two miscible liquids. These type of mixtures are easy to prepare. b. Negative Mixtures: These mixtures are prepared by mixing insoluble solids in a vehicle in case of suspension or by mixing two immiscible liquids in case of emulsion. These mixture require high degree of energy or external force. c. Neutral Mixtures: Some products such as Pastes, ointments etc do not mix spontaneously but after mixing they do not separate out easily. These are called neutral mixtures.

8.3 OBJECTIVESOF MIXING Mixing can be done for the following reasons. 1. Mixing is a critical process. The quality of final product depends upon the nature of mixing. Improper Mixing lead to non homogeneous products. 2. Proper Mixing lead to decrease batch cycle ~mes and operational cost. 3. To increase the dissolution or diffusion rate

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8.4 APPLICATIONS Mixing is one of the common pharmaceutical Pharmacy which are in practice: a. b. c. d. e.

operation. There are few examples of large scale Mixing in

Mixing is an intermediate step in production of tablet or capsule. Mixing of powders in different proportion prior to granulation or tab letting Dry mixing of materials for direct compression into tablets. Dry mixing of powders & composite powders in capsules and insufflations respectively. Blending of powders are also important in preparation of cosmetic products such as facial powder or dental powder In case of potent drugs where dose is low, mixing is critical factor. Otherwise it will affect content uniformity of tablet.

8.5 FACTORSAFFECTING MIXING OPERATION I.

2.

3. 4.

5. 6.

7.

8. 9.

10. 11. 12.

13.

Nature of the product:

For effective mixing particle surface should be smooth. Rough surface of one or more components lead to increase chances of entry of active substance into the pores of another ingredient and further affect mixing. Particle size: It is easier to mix powders of same particle size. Variation in particle size lead to improper mixing. Increasing the difference in particle size will lead to segregation (size separation), since small particles can fall through the voids between the larger particles Particle shape: The particle should be spherical in shape to achieve uniform mixing. Particle charge: Some particles due to electrostatic charges exert attractive force which lead to separation. Proportion of Material: It is easy to mix powders if available in equal quantities. But to mix small quantities of powders with large quantities of ingredients is difficult process. Relative density: If the components have a different density, the denser material will sink through lighter material, the effect of which will depend on the 'relative positions of the material in the mixer. Viscosity: The mixing is also affected by the viscosity. An increase in viscosity reduces the extent of mixing. More viscous particles cause poor mixing. Surface tension of liquids: The surface tension of the liquid is also an important factor affecting the mixing. High surface tension reduces the extent of mixing. Temperature: The temperature also affects the mixing because the viscosity changes with the change of temperature Mixer volume: The volume of the mixin g also affects the mixing phenomena. The blender volume should be such that overfilling should not be done as it decreases the mixing efficiency Agitator type: The shape, size, location and type of agitator also affect the degree of mixing achieved and the time required to mix specific components. Speed I rpm of the impeller: The speed of the impeller affects the homogeneity of the mixing. As mixing at less rpm is more homogeneous than at a higher rpm. Mixing time: The mixing time is also very important for appropriate mixing. There is always an optimal mixing time for the specific conditions in which the mixing is taken place.

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8.6 EVALUATION

OF DEGREE OF MIXING

The degree of mixing is evaluated by comparing standard deviation of sample under investigation (Sr) with estimated standard deviation of sample from fully random mix (S0. It is expressed by Lacey.

Mixing Index (M) = Sa I SI

(8.1)

Higher the value of mixing index, greater will be homogeneity.

8.7 TYPE OF MIXING Mixing are of different types Solid-solid Mixing, Liquid-liquid Mixing, Solid-Liquid Mixing

Table 8.1 Difference between solid and liquid mixing Liquid Mixing

SoHdMixJng In this two or more substances continuous movement of particles.

are intermingled

by

This is achieved by mixing element of suitable shape to act as impel\er to produce appropriate flow pattern in mixing vessel

This is used for mixing of dry powders

This is used in preparation of emulsion, suspension and mixtures

Large sample size is required

Small sample size is sufficient

High power required for mixing

Less DOwerrecuired for mixing

8.8 SOLID-SOLID MIXING Material having similar physical properties will be easier to form a uniform blend or mixture compared to the difference in properties. It is more difficult to achieve a good mixing of particulate solids of different sizes and densities. material density, particle size and distribution, wettability, stickiness, particle shape I roughness are the physical properties that affect mixing process. The mechanism involved in solid solid mixing are

Convective Mixing, in which the groups of particles move from one position to another. It is also referred to as macrornixing.

Shear Mixing In this, shearing forces are created within the mass of the material by the use of a stirring arm or a burst of air.

Diffusive Mixing: During this mixing, gravitational forces cause the upper layers of materials to slip and random motion of the individual particles takes place on newly developed surfaces. This is also sometimes known as rnicromixing.

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8.9 EQUIPMENTS A wide variety of equipments are used for mixing powders on industrial scale. During mixing of powder, a few points should be considered so that proper mixing can be achieved. The mixer should have sufficient space for mixing. It should not be Overfilled. It reduces efficacy of mixing. The shearing force should be sufficient so that aggregation can be prevented. The forces used should not cause breakage of particles. The selection of appropriate mechanism is more important and also there should be optimum time for mixing. Some Mixing equipments are discussed below

8.10 DOUBLE CONE BLENDER Principle: The mixing occur due to tumbling motion. Construction: All parts of equipments including mixing tank and blades are made of stainless steel. The equipment consist of two cones joined as cylindrical section which are rotated about an axis on the shaft. The conical shape at both ends allows uniform mixing and easy discharge .

• Figure 8.2: Construction of Double Cone Blender Working: The powder is filled up to two third of volume of blender to ensure proper mixing. The rate of rotation should be 30-1 ()() revolutions per minute. On rotation mixing occur due to tumbling motion. The product can be discharged from the bottom of the equipment. The mixing tank can be slanted freely at the angle of 00 to 3600 degrees for discharging and cleaning purpose. Advantages: 1. Easy to maintain and clean 2. There are no chances of clogging of material into corners 3. Large amount can be handled easily 4. It is efficient for mixing powders of different densities 5. Wear on equipment is little

Disadvantages: 1. Not suitable for fine particles 2. Not suitable for particles with greater particle size difference due to less shear

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Pharmaceutical AppUcation 1.

2.

Double Cone Blender is an efficient and versatile equipment for the homogeneous mixing of dry powders and granules. Dry powder mixing for tablets and capsule formulations. It can be used for pharmaceutical, food, chemical and cosmetic products etc.

8.11 TWIN SHELL BLENDER OR V CONE BLENDER Principle: The mixing occur due to tumbling motion.

Shaft drive

Figure 8.3: Construction

or Twin

shell blender

Construction It consists of a totally enclosed V shaped vessel which prevent any foreign particle to enter into chamber. It is made of either stainless steel or transparent plastic. It consists of horizontal shaft rotated about an axis causing the particles within the mixer to tumble over each other onto the mixture surface. The charging of material into the V-Blender is through either of the two ends. Batches from 20 kg to 1 tonne can be loaded for mixing depen?ing upon the size of equipment.

Working The material is loaded into the blender. The recommended fill-up volume for the V -Blender is 50 to 60% of the total blender volume. On rotation, a tumbling motion occurs. When the V-Blender tumbles, the material divides and recombines continuously. The repetitive converging and diverging movement between the material and the blender results homogenous blending. The product is collected from the bottom of V. Normal blend times are typically in the range of 5 to 15 minutes depending on the properties of material to be blended. Blender speed can also be key to mixing efficiency. At low speeds, shear forces are less. Although higher mixing speeds provide more shear, this can lead to greater dust resulting from the segregation of fines. There is also a critical speed which, if approached, will considerably reduce the mixing efficiency. As revolutions per minute increase, the centrifugal forces at the extreme points of the blender will exceed the gravitational forces required for mixing. As a result, the powder must tend to gravitate toward the outer walls of the blender casing. As the size of the blender increases, the rotational speed generally decreases in proportion to the peripheral speed of the blender extreme. V-Blenders are designed to operate between 50% and 80% of the critical speed.

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Advantages 1. V-Blenders are therefore preferred when precise blend formulations are required. 2. They are also well suited for applications where some ingredients may be as low as five percent of the total blend size. 3. Particle size reduction and attrition are minimized due to the lack of moving blades. Therefore, it can be used for fragile materials 4.

Loading and unloading of material is easy

5. 6.

The absence of shaft projection reduce chances of product contamination. Easy to clean

Disadvantage 1. 2.

They require high headroom for installation and operation. They are not suitable for blending particles of different sizes and densities. There are chances of segregation of these particles at the time of discharge.

Pharmaceutical Applications 1. V blenders are used for dry mixing. It provide efficient blending in short time. 2. This blender is often used for pharmaceuticals. But not suited for very soft powders or granules. 3.

V-Blenders are generally used for the FOQd products, Milk powder, Dry flavors, Pesticides Herbicides, Animal feed, Spice blends, Baby foods and Cosmetics

and

8.12 V-BLENDER WITH INTENSIFIER BAR OR AGITATOR BLADES Intensifier Bar Direction of Rotation

,

Blender Shaft Intensifier Bar Shaft Axis of Rotation

Figure 8.4 : V-Blender with Intensifier Bar The general construction and operation are the same as those of the V cone blender. In addition, V -Blender can be equipped with high speed intensifier bars (or agitator blades) with spray pipes for addition of liquid. The Intensifiers may be provided for the disintegration of agglomerates which are formed during wet mixing.

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Advantages: 1. Suitable for both dry and wet mixing. 2. Suitable for mixing of fines and particle compositions. 3. Suitable for mixing of cohesive powders. Disadvantages: 1. Undesirable attrition of particles. 2. Sealing problems of the shaft of the Intensifier bar. 3. Cleaning issues

8.13 RIBBON BLENDER Principle The mechanism of mixing is shear which is transferred by moving blades. Construction A ribbon blender consists of a U-shaped horizontal trough or shell containing a helical double-ribbon agitator that rotates inside. The shaft of the agitator is positioned in the center of the trough on which the helical ribbons (also called spirals) are welded. Since the ribbon stirrer consists of a set of internal and external helical ribbons, it is also called a "double" helical ribbon agitator. The counteracting blades are provided for high shear as well as for breaking of lumps or aggregates. The ribbon blenders are powered by a drive system consisting of a motor, a gearbox and couplings. They are generally powered by 10 HP to 15 HP motor for 1000 kg of product mass to be blended. The specific power ranges from 3 to 12 kW / m3 according to the products to be mixed. The area where the shaft exits the container is envisaged with a Sealing arrangement to ensure that the material does not move from the container to the outside. The material is charged into the mixer usually by feed hoppers. It is also equipped with bottom discharge spout. Helical blades Mixer Shell

Drive shaft

Discharge spout Figure 8.5: construction of Ribbon Blender

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Working The materials to be blended are loaded into the blender, typically filling it between 40 and 70 percent of the total volume of the container. Ribbons are allowed to rotate with the help of the drive system. During the blending operation, one blade slowly moves the solids in one direction and the other moves them rapidly in the opposite direction. As a result, the homogeneous blending is achieved in a short time. The mixing is generally carried out in 15 to 20 minutes. After blending, the material is discharged from a discharge spout located at the bottom of the trough. Particle size and bulk density have the strongest influence on the mixing efficiency of the ribbon mixer. Ingredients having a similar particle size and bulk densities tend to mix faster than the ingredients with a variation of these attributes.

Advantages 1. Ribbon blender can be operated in both batch and continuous modes. 2. 3.

High shear by baffles cause break down of aggregates Less headspace requirement

Disadvantages 1.

It is practically difficult to obtain 100% discharge in the ribbon blender.

2.

Higher clearance between the external periphery of the outer ribbon and the container may result in unmixed or dead spots.

3.

The movement of ribbons near the vessel walls due to high shear and compression can damage fragile materials and cause attrition.

Variant An alternate design of the ribbon agitator is the paddle agitator which can handle a fragile material. The paddle agitator is composed of both forward and reverse paddles in place of the ribbon. The paddles are positioned to move the material in opposing lateral directions as well as in a radial direction. The paddle design is generally used when friable materials are mixed, and when batches as small as 15% of the total capacity are going to be blended into the blender

Pharmaceutical applications Ribbon blender is used for blending large volumes of dry solids, wet solid mass, bulk drugs, chemicals, and cosmetic powders.

8.14 SIGMA BLADEMIXER Principle The mechanism of action is shearing which is produced by inter meshing sigma shaped blades. It belongs to the family of double arm kneader mixers.

Construction It consist of two mixing blades, which shapes resemble the Greek letter sigrna (L ) , are fitted horizontally in each trough of bowl. The clearance between the blades and the vessel walls is low (-2 mm). The low clearances produces high shear.

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Direction of rotation Blades

Intermeshing Blade design

Drive shaft END VIEW SIDE VIEW Figure 8.6: Construction of Sigma Blade Mixer Working The powders (40 to 65 percent of the mixer's total volumetric capacity) are introduced from the top of the trough. The entire process is carried out in a closed enclosure because the dust can be released. The blades move at a different speed using the drive system. that includes motor, gear reducer, couplings, gears, bearings and seals. The material moves up and down and shear occurs between the blades and the wall of the trough. The equipment is also attached to the perforated blades to break lumps and aggregates. The discharge of the material is either by tilting the mixing vessel, through bottom discharge valve, or through a discharge screw.The homogeneous mixture is obtained in 10 to 30 minutes. Mixing homogeneity up to 99%.

Advantages 1. During mixing, minimum dead space is created. 2. lumps and aggregates broken by perforated blades 3. Loss of volatile solvent during mixing can be prevented by closing the chamber.

Disadvantages 1. The power consumption in double arm kneader mixer is very high compared to other types of mixers and can range from 45 to 75 kW/m3 of mix material 2. Both blades rotate at same speed.

Pharmaceutical AppUcatlons 1. The sigma blade mixer is a commonly used mixer for high viscosity materials. 2. Sigma blade mixers are used for wet granulation process in the manufacture of tablets, pill masses and ointments. 3. It is primarily used for solid-liquid mixing and also for solid-solid mixing.

8.15 PLANETARY MIXERS Principle It works on the principle of shear that develops between the stationary wall and the rotating blade. The blade is also used to reduce the size. The planetary blades rotates on their own axis while they travel around the centre of the mixing bowl which ensures complete and effective mixing.

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Shell Beater or __ Blade

--r

Figure 8.7: Planetary Mixers Construction It consists of a vertical cylindrical shell or bowl that can be removed. The shell or bowl is covered and may be provided with nozzles, a liquid spray arrangement or viewing ports. The material can be loaded into the mixer either through the nozzles on the top cover, or directly loaded into the mixer bowl. The mixer has two blades that rotate on their own axes when they orbit the mixing container on a common axis. The mixing blade is mounted at the top of the shell. The drive system consists of a motor and a gearbox that drives the planetary head. Each planetary blade is generally driven by gears that rotate due to the movement of the planetary head.

Working The material to be mixed is loaded into mixing bowl or shell. The blades rotate on their own axis when they orbit the mixing bowl on a common axis. Therefore there is no dead spot in the mixing and high shear is applied for mixing. After mixing, the material is discharged through a bottom valve, or by manual scooping of the material from the bowl.

Advantages 1. 2. 3. 4. 5.

Simple construction, operation, and relatively lower cost No dead spot in the mixing Rotation speed of blades can be varied Used for wet granulation process High mixing efficiency

Disadvantage 1. 2.

Require high power Heat build up within powder mix

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8.16 LIQUID-LIQUID MIXING Liquid liquid Mixing require shear to form homogenous Liquid- liquid mixing is simple in operation.

system. As compared to solid- liquid mixing ,

8.16.1 Type of liquid Mixture 1. 2. 3.

Miscible liquids: They mix with each other in all proportion. For example: Mixture of ethanol in water. Their mixing is quite easy and this type of mixing does not create any problem. Partially miscible liquids: These liquids mix with each other at specific proportion. For example: Mixture of P-cresol and water. Their miscibility based on temperature and pressure. Immiscible liquids: They are not miscible. For example: Vegetable oil and water mixture. They form heterogenous mixtures e.g. emulsions. A homogenous dispersion may be obtained by adding emulsifying agents.

8.16.2 Mechanism

of mixin2

The mechanism of liquid mixing are 1. 2.

3.

4.

Bulk transport: It is the movement of large portion of material from one location to another location. The movement is done by rotating blades or paddles. Turbulent Mixing: In this, mixing is due to turbulence. Turbulence is a function of velocity gradient between two adjacent layers of a liquid. In turbulent flow there is random fluctuation in fluid velocity at a given point within the system. The turbulent flow can be easily visualized as a composite of eddies of different sizes. An eddy is defined as a part of the fluid moving as a unit in a direction often contrary to that of the general flow. Laminar Mixing I Streamline Mixing: When two dissimilar liquids are mixed through a laminar flow, the shear that is generated stretches the interface between them. In this mechanism the layers folds on themselves. As a result the number of layers, and therefore the interfacial area between them, increases exponentially with time. Molecular Diffusion: The mechanism responsible for mixing at the molecular level is the diffusion resulting from the thermal movement of the molecules. The process is described in terms of Fick's law of diffusion:

dc

Dm _ DA ---dt

dx

Where, Dmldt is the rate of transport of mass across an interface. A is the area dc/dx is the concentration gradient across the interface D is diffusion coefficient

8.16.3 Flow Pattern

during mixing

The movement of the liquid at any point in the vessel will have three velocity components I.

Radial components,

2.

Longitudinal

act in a direction vertical to the impeller shaft.

component,

act parallel to the impeller shaft.

(8.2)

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Tangential component, act in a direction that is a tangent to the circle of rotation round the irnpellershaft

8.17 MIXING EQUIPMENTS Mixing devices are known as irnpellers. Impellers operate using a combination of radial, axial and tangential flow Three main type of irnpellers are: Propellers, Turbines and Paddles.

8.18 PROPELLERS Propellers are the mechanical device that are used to mix liquid materials by using blades. A three bladed design is generally used for liquids. The mixing is done by mixing a imrnisible liquid with the other miscible liquid to form the real solutions. These mixers work primarily on shear forces using different types of blades. Twisted blades

Shaft

Figure 8.8: Three bladed design

Propeller Mixer PRINCIPLE The propeller mixer mainly works on the principle of shearing force. Construction It consist of vessel and propeller. A propeller has angled blades, which cause the fluid to circulate in both an axial and a radial direction. Size of propeller is small and may increase upto 0.5 meters depending upon the size of tank. Small size propellers can rotate upto 8000 rpm

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:

.

t t

: (-"-,.,,) .. .. '.'

.

'.

~

... .

'.'

Axial flow

..

.' "

Radial flow

Figure 8.9: Flow pattern

during mixing

Working A vortex forms when the centrifugal force imparted to the liquid by the propeller blades causes it to back up around the sides of the vessel and create a depression at the shaft. As the speed of rotation is increased air may be sucked into the fluid by the formation of a vortex this cause frothing and possible oxidation. Another method of suppressing a vortex is to fit vertical baffles into the vessel. otor

...--1-++ Shaft

Vortex formation

Baffle +--~ Impeller (a)

(b)

Figure 8.10 (a) Baffled tank with no vortex formation (b) unbamed

and

tank having vortex formation

Installation of Vertical Propeller reduce the vortex to considerable extent. Vertical propeller mixer consist of three blades (4 ft long). Horizontal or inclined propeller or marine propeller are also used on side-entry mixers. They are ted with the impeller shaft inclined at an angle to the vessel axis to improve the process results. They vide good blending capability in small batches of low to medium viscosity.

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Figure 8.11: Marine type propeller Pharmaceutical Applications The propeller mixer used for mixing the liquids having maximum viscosity of 2.0 Pascal-second, for mixing of low visocity emulsions and also used in mixing of suspensions with particles size upto 0.1 to 0.5 mm. Advantages Propellers are effective when high mixing capacity is required. Disadvantages 1. 2.

Propellers are not effective for liquids having viscosity greater than 5.0Pascal second Equipment Cost is high

8.19 TURBINES A turbine mixer is a mechanical device that are used in the mixing of different types of liquids. The turbine mixer works mainly on the principle of shearing action. It consists of the number of blades attached to the circular disk. The blades used in these mixers are of various types: flat blades, disk-type flat blades, inclined blades, curved blades, inclined blades, arrowhead blades, curved blades, and so on. The diameter of the turbine varies from 30 to 50% of the diameter of the vessel. As compared to propeller, Turbines rotate at a lower speed (rpm).The mixing action is accomplished by the turbine blades. When turbine mixers operate at sufficiently high rotational speeds, the radial and tangential flow becomes pronounced with the formation of vortex. It is necessary to install baffles in the vessel for the mixing process for uniform mixing. The radial flow of the impeller impinges on vessel walls, where it splits into two streams.

Figure 8.12 Straight Blade turbine

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Figure 8.13 Disc turbine

Figure 8.14 Pitched blade turbine

Figure 8.15 Curved vane turbine

Uses A turbine mixer suitable for viscous fluids (having viscosity 7.0 pascal-second), Turbines are also used for thin paste and emulsification. Turbines can also used to handle slurries with 60% solids. Turbines are mainly used for semisolid materials. Advantage Turbines give greater shearing forces than propellers

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8.20 PADDLES

Shaft Flat blade

Figure 8.16 Paddle Paddle consist of two long flat blades attached vertically to shaft. It rotates at low speed. Paddles mixer are suitable to mix viscous liquids or semisolids. A variety of paddle mixer are available depending upon nature and viscosity of product. Blades used in this mixer are dished or hemispherical in shape. Paddles push liquid radially and tangentially. There is no axial movement of flow during mixing. The diameter of paddle is 5080% of inside diameter of vessel. Advantages 1. Vortex formation is not possible. 2. It has low speed. 3. Mixing efficiency is better. 4. No dead spots and deposited solids. Disadvantages In case of suspension mixing is poor. Therefore baffled tanks are required

8.21 SILVERSON EMULSIFIER Two immiscible liquids are mixed to prepare an emulsion is widely used in pharmacy. The equipment used for preparation of emulsion is known as emulsifier. Homogenizer are used to convert coarse emulsion to fine emulsion. Principle The sliverson homogenizer works on the principle that the large globules in a coarse emulsion are broken into smaller globule by intense shearing forces and turbulence by high speed rotors. Construction It consists of a emulsifier head. The emulsifier head consist of a number of turbines blades. The blades are surrounded by mesh which is enclosed by cover having perforations. The blades are rotated by using the electric motor fitted at the top. There is also one shaft whose one end is connected to motor and other end is connected to head.

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Electric motor

~I-+Shaft Stand

Emulsifying head

Figure 8.17: Construction OrSilverson Emulsifier

Working The emulsifier head is dipped into the vessel containing immiscible liquids. When the motor is started, shaft rotates the head. Therefore turbines blades also rotate at very high speed. The liquids are sucked through the fine hole. Centrifugal force expel content through mesh and then to cover and subjects them to mechanical shear. This is followed by intense hydraulic shear. The oil is reduced into the globules quickly resulting in a homogeneous, uniform product. Then fine emulsion emerge through opening of cover. As a result bigger globule rapidly break into smaller globules.

Pharmaceutical Applications 1. 2. 3. 4.

Silverson Mixer Homogenizers are fast and efficient. They are used to get a fme droplet or particle size (2 - 5 microns). Process efficiency is good. Low operating cost. It is used for preparation of creams, ointments, pharmaceutical suspensions and emulsions of fine particle size.

Disadvantage 1.

Chances of choking of pores of mesh.

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QUESTIONS

VERY SHORT ANSWER QUESTIONS Q1. Define Mixing Answer- It is defined as a process in which two or more components within a system are converted into one mass or mixture. Q2. Define Convective Mixing. Answer- These are the mixing in which the groups of particles move from one position to another. It is also referred to as macromixing. Q3. What are Diffusive MixIng? Answer- During this mixing, gravitational forces cause the upper layers of materials to slip and random motion of the individual particles takes place on newly developed surfaces. This is also sometimes known as micromixing. Q4. Define Laminar Mixing. Answer- This type of mixing occur when two dissimilar liquids are mixed through a laminar flow, the shear that is generated stretches the interface between them. QS. What are PropeUers? Answer- These are mechanical device that are used to mix liquid materials by using blades.

SHORT ANSWER QUESTIONS Q1. The Mixing is carried out In a closed enclosure, Why? Answer- Mixing is carried out in closed enclosure to avoid release of the dust. And the loss of volatile solvent during mixing can also be prevented by closing the chamber. Q2. Write disadvantage of double cone blender. Answer- It is not suitable for fine particles and also not suitable for particles with greater particle size difference due to less shear. Q3. How degree of mixing is evaluated? Answer- The degree of mixing is evaluated by comparing standard deviation of sample under investigation (Sv with estimated standard deviation of sample from fully random mix (SR) Mixing Index (M) = SR I SI Q4. How V blender Works? Answer- The material is loaded into the blender. On rotation, a tumbling motion occurs. When the V-Blender tumbles, the material divides and recombines continuously. The repetitive converging and diverging movement between the material and the blender results homogenous blending. QS. What are the uses of propeUer mixer? Answer- Propeller mixer are used for mixing the liquids having maximum viscosity of 2.0 Pascal-second, for mixing of low visocity emulsions and also used in mixing of suspensions with particles size upto 0.1 to 0.5 mm maximum with a drying residue of 10%

LONG ANSWER QUESTIONS 1. 2. 3.

Define Mixing Index. Write the differences between solid and liquid mixing (Refer article 8.7) Describe Principles, Construction, Working, uses, Merits and Demerits oftwin shell blender. (Refer article 8.11) Describe Principles, Construction, Working, uses, Merits and Demerits of ribbon blender. (Refer article 8.13)

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4.

Describe Principles, Construction, Working, uses, Merits and Demerits of Sigma blade mixer. (Refer article 8.14)

S.

Define mixing. Describe the factors affecting mixing operations. (Refer article 8.1,4.5)

6.

Describe Principles, Construction, Working, uses, Merits and Demerits of Silverson Emulsifier. (Refer article 8.21)

7.

Write short note on a. Turbines (Refer article 8.19) b.

8.

Paddles (Refer article 8.20) Write short note on a. Propellers (Refer article 8.18) b. Application of mixing (Refer article 8.4)

MULTIPLE CHOICE QUESTIONS 1. Which of the following is not the mechanism involved in solid solid mixing? a. Convective b. Shear c. Diffusive d. Bulk transport 2. Which of the following is suitable mixing equipment for two immiscible liquids a. Silverson emulsifier b. Double cone blender c. Ribbon blender d. twin shell blender 3. Vortex formation take place a. In unbaffled tanks b. At high impeller speed c. When blades in turbines are arranged perpendicular to central shaft d. All of the above 4. Which of the following is also known as V Cone Blender? a. Twin shell blender b. Double cone blender c. Ribbon blender d. Colloid mill S. Which of the following is example of static mixer a. Ribbon blender b. V cone blender c. Double cone blender d. Silverson emulsifier

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6.

r

In sigma blade Mixer, the clearance between the blades and the vessel walls is a. Low b. High c. Moderate d. None of the above

7.

Silverson mixer is used for preparation a. lotion b. Emulsion c. Elixirs d. Suspension

8.

Which of the foUowing rate is observed during mixing of soHds? a. First order law b. zero order law c. Second order law d. ThiCd order law

9.

Pharmaceutical Engineering

The a. b. c. d.

of:

movement of large portion of material from one location to another location is caUed Bulk transport Diffusion Agitation Convection

10. Higher the value of mixing index, greater will a. Homogenity b. Solubility c. Viscosity d. Density

_ I

•

ANSWERS I.d

2.a

3.d

4.a

s.a

6.a 7.b 8.a

9.a

10.a