Mixing and Agitation Techniques PDF

Summary

This document provides an overview of various mixing and agitation techniques, discussing different types of agitators and their applications, including their use in food, chemical, and pharmaceutical industries, and their role in creating uniform mixtures from heterogeneous physical systems. The different flow patterns (axial and radial) are also highlighted, along with their pros and cons in different applications.

Full Transcript

**Agitation** of liquids. The unit operation is **used to prepare
liquid**--mixture by bringing in contact two liquids in a mechanically
agitated vessel or container. Agitation refers to the induced motion of
liquid in some defined may, usually in circulatory pattern and is
achieved by some mechanical device

Agitation is the **process of providing bulk motion to a liquid.**

Agitation & Mixing of fluids - ppt download

**Kneading** is a process in the making
of [bread](https://en.wikipedia.org/wiki/Bread) or [dough](https://en.wikipedia.org/wiki/Dough),
used to mix the ingredients and add strength to the final product.
Kneading is the **process that brings the dough together, develops the
strands of gluten and creates a silky and strong dough ready to be
baked**.


**Mixing (or blending)** is a unit operation **in which a uniform
mixture is obtained from two or more components**, by dispersing one
within the other. Hence it is a process which involves manipulating a
heterogeneous physical system, with the intent to make it more
homogeneous.

**Homogenization** is an **essential unit operation during the
manufacture of a number of food and dairy products**. As a unit
operation, homogenization performs multiple functions such as reduction
of particle size, dissolution, mixing, dispersion, encapsulation, and
emulsification.

**Types of Agitators**
----------------------

1. 2. 3. 4. 5.

### 1. **Turbine Agitators**

These agitators have an axial input and the output is radial. Turbine
agitators are very versatile; they are able to handle a wide variety of
mixing operations because these agitators can create turbulent movement
of the fluid due to the combination of rotational as well as centrifugal
motion. They are popularly used in metal extraction industries and also
for chemical reactions and have a very high blending efficiency. These
are mostly used in chemical, pharmaceuticals, grease, cosmetics
industries.

Turbine Agitator

### 2. **Paddle Agitators**

It is one of the most basic types of agitator. It contains blades which
are paddle shaped; the blades stretch throughout the vessel and reach
the walls of the vessel. They are primarily used in applications where a
uniform laminar flow of the liquids and little shearing is desired. This
type of agitator is especially used for viscous materials. These are
mostly used in food, chemicals, pharmaceuticals, sorbitol etc industries


### 3. **Anchor Agitators**

As the name indicates the shape of the impeller resembles that of the
anchor. These agitators also extend and spread throughout the vessel
such that there is very less clearance between the blades and the walls
of the vessel. These agitators are also used when laminar flow
conditions are desirable. These impellers sweep the whole batch because
the blades are almost in physical contact with the walls of the vessels.
These agitators are used in ink, paint and adhesive industries.

### Anchor Agitators

**4. **Propeller Agitators: These have impellers that similar to marine
type propellers. They have blades which taper towards the shaft to
minimize centrifugal force and to promote axial flow. It means when this
agitator operates the motion of fluid is such that the inlet flow is
parallel to the shaft and the outlet flow is also parallel to the shaft,
the ideal flow is axial in nature. They are primarily used in
applications to stir low viscosity liquids. They are used in
pharmaceuticals industries and also other industries which use
suspensions as the agitators don't let the solid particles settle.

### 

### 5. **Helical Agitators**

### The blades of the helical agitators are arranged in a structure of helix. The appearance is similar to how a threaded screw looks. The motion of the liquids in this type of agitator is also axial in nature due to the way the blades or the ribbons move while helical agitator is in operation. There is a vigorous motion of the fluids within the vessel when the agitator is in operation. It is used in polymer industries and other industries which require the use of quite viscous materials.

Helical Agitators


**Flow Pattern based impeller:** The most common flow patterns in mixing
are **axial** (down and up) and **radial** (side to side) flow. These
flow patterns also describe the generic classes of impellers: axial and
radial.

----------------- ----------------------------------------
Axial Impellers 
----------------- ----------------------------------------

### 1. Axial Flow Impellers

Axial (down and up) pumping is an important flow pattern because it
addresses two of the most common challenges in mixing;
solid [**suspension**](https://dynamixinc.com/mixing-101-the-basic-principles-of-mixing-and-impellers/#solid-suspension) and [**stratification**](https://dynamixinc.com/mixing-101-the-basic-principles-of-mixing-and-impellers/#stratification).
In this process both the superficial and annular velocities can be
calculated to determine and control the level of mixing. (If your axial
impeller is causing swirling or vortexing, check out our
previous [**Mixing 101 posting Baffled by
Baffles**](https://dynamixinc.com/baffled-by-baffles)?)

Here are some of the most common axial impellers:

+-----------------------------------+-----------------------------------+
| #### A. Marine-type Propellers | Marine-Type Propellers |
| | |
| [**Viscosity**](https://dynamixin | |
| c.com/mixing-101-the-basic-princi | |
| ples-of-mixing-and-impellers/#vis | |
| cosity): | |
| 0 -- 5,000 cps | |
| | |
| Commonly used on marine boats, | |
| the propellers are often used in | |
| small portable direct drive mixer | |
| applications because they're | |
| economical and efficient. | |
| However, in larger applications | |
| they're seldom used because of | |
| their price and weight. | |
+===================================+===================================+
| #### B. Pitch | ![Pitched |
| | Impellers](media/image12.png) |
| **[Viscosity](https://dynamixinc. | |
| com/mixing-101-the-basic-principl | |
| es-of-mixing-and-impellers/#visco | |
| sity):** 0 | |
| -- 50,000 cps | |
| | |
| The pitch blade impeller is the | |
| most versatile impeller and was | |
| the standard until the | |
| development of the airfoil. | |
| They're useful in blending two or | |
| more liquids and are effective in | |
| low bottom clearance with less | |
| liquid submergence. | |
+-----------------------------------+-----------------------------------+
| #### C. Dynaflow^TM^ (Hydrofoils) | Hydrofoil Impellers |
| | |
| **[Viscosity](https://dynamixinc. | |
| com/mixing-101-the-basic-principl | |
| es-of-mixing-and-impellers/#visco | |
| sity):** 0 | |
| -- 3,000 cps | |
| | |
| The camber of the blade increases | |
| the efficiency of the impeller, | |
| reducing its power / pumping | |
| ratio. A more technical benefit | |
| is the laminar flow created by | |
| the camber of this impeller. This | |
| camber reduces turbulence (shear) | |
| substantially. That is why it is | |
| selected for shear-sensitive | |
| applications as well. | |
+-----------------------------------+-----------------------------------+

### 2. Radial Flow Impellers

------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
Unlike axial impellers, radial impellers are commonly selected for low level mixing (known as a tickler blade) or elongated tanks. They typically give high shear rates because of their angle of attack. They also have a relatively low pumping number, making them the most sensitive to viscosity. Radial impellers do not have a high tank turnover flow like axial flow impellers.
------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------

**FLOW PATTERN**

**Axial flow** is the most efficient flow for bulk blending. With axial
flow, the individual blades on the propeller are angled downward. When
the blade spins, it pushes the mixture down towards the bottom of the
tank. As the mixture hits the bottom of the tank, it bounces off and
moves towards the sides of the tank. The continued force of the moving
blade moves the mixture up the sides of the tank, and then begins to
recirculate as the spinning blade pulls in the mixture from above. This
type of flow provides great mixing for a wide range of conditions. Also,
if you are looking for a way to suspend solids in a liquid mixture
(think of suspending sugar in hot tea in order to give it time to melt)
this is the kind of flow you'll want.

**Radial flow** pushes the mixture out towards the side of the tank.
Part of the mixture hits the side of the tank and moves downward, while
the other part hits the side of the tank and moves upward. Radial flow
mixing is great for intense mixing needs like when you need to break
down the molecular bonds of the items that you are mixing. Also, radial
flow generally has a slower blending time than axial flow.

**Rotational flow** is usually avoided or limited. With rotational flow,
the mixture moves around the shaft of the mixer without really getting
mixed. If you dropped a ball into a tank mixing water with a rotational
flow, the ball would essentially orbit the shaft of the mixer without
moving up or down in the container. Rotational flow spins liquids around
the without mixing them. However, rotational flow can break the surface
tension of the mixture by creating a vortex. This can be used helpful
for adding other liquids and solids into the mixture.

**Prevention of Swirling and Vortex Formation **

There are three methods for the prevention of swirling and vortex
formation: 

 (i) Off-centre mounting of the impeller. 

 (ii) Use of baffles. 

 (iii) Use of diffuser ring with turbines. 

![Fig. a : Vortex formation and circulation pattern in an unbaffled
agitated vessel](media/image14.jpeg)

Vortex Formation

- In small vessels, the impeller can be mounted off-centre

- In large vessels with vertical agitators, the most common method of
reducing swirling is to install baffles along the side of the
vessel, which hinder rotational flow  without disturbing radial or
longitudinal flow.  

- In an unbaffled vessel, there are strong tangential flow currents
and vortex formations at moderate speeds but in the presence of
baffles, the vertical flow currents are  increased and there is more
rapid mixing of the liquid. 

- With side entering, inclined and off-centre propellers, baffles are
not needed

Fig. c : Propeller‚ off-centre and angular (unbaffled)

**Propeller‚ off-centre** **and angular (unbaffled)**


**Side entering propeller**

Flow pattern with turbine impeller in baffled tank

**Flow pattern with** **turbine impeller in baffled tank**

#### Horizontal Mixers

A horizontal mixer gives you a clear advantage when you're trying to mix
thousands of pounds of dough in a very short amount of time.
Medium-to-large-sized bakeries and factories depend on this type of
machine because of its sheer size and capability.

**Horizontal Mixers** consists of ribbon, plough and paddle mixers,
which are designed for consistent batch and continuous blending of
powder and granules with capacities ranging from 35 -- 60,000 litres.

This type of mixer is perfect for the mixing of things like short
doughs, tortillas, fillings, pie doughs, health breads, cheesecakes,
muffins and many other things.

Horizontal mixers come with a selection of mixing arms that allow you to
customize based on the type of dough you are mixing. They also allow for
continuous mixing, meaning once the mixed dough comes out, exiting
easily into a trough, the next batch can go into the machine on the
other end.

The **disadvantage** to this choice is that heat generation is a
concern. The friction from the dough rubbing on the sides of the mixing
chamber causes the dough temperature to rise, which can be damaging to
some types of dough. It is important to take this into consideration
when choosing the right mixer, especially if you plan on mixing mostly
bread doughs.

--------------------------------------------------------------------------------------------------------------------

Operations
----------

The horizontal mixer provides a superior uniform mix of a wide range of
materials from free flow material to high density wet material such as
plastics chemicals liquids molasses, minerals and detergents, live stock
feed for poultry and cattle adding premixes and vitamins. Its \"U\"
shape body is manufactured in a robust heavy-duty construction in
painted carbon steel or stainless steel. The effective speed and the
specially designed agitator gives the Horizontal mixer a fast time of
mixing with 100% accuracy and homogenity. The discharging of the mixer
is either done Manually or Pneumatically through operated outlet or
slide gate. Mixers are equipped with either a low speed Gearbox motor
attached to the main shaft with a chain and sprocket or a speed reducer
driven by a motor with a V belt drive.

Side bearings holding the main shaft are either bolted to the sides of
the mixer directly or away from the sides with a special stuffing boxes
installed for preventing ingredients getting into the bearings. The
Horizontal mixer is manufactured in various capacities and sizes from
small SH, medium MH, and large LH. Horizontal mixers are equipped by
either a Ribbon or a Paddle agitator.The Ribbon Agitator consists of a
set of inner and outer helical ribbons that circulates the material from
end to end inside and outside, it is recommended to be used for the
mixing of free flow material. moreover Ribbon agitator are designed for
center discharge or multiple side discharge position. The Paddle
agitators uses a lifting and tumbling circulation of materials from end
to end and its is recommended to be used with heavy resistant material
for both wet or dry ingredients. They are also designed for center or
side discharge position. Both Agitators are manufactured to result a
fast yet efficient and accurate blending.

Common Applications
-------------------

- - - - - -

**Video link for visualization:**

**Planetary Mixer**

**Video link for visualization:
**

**Sigma Blade Mixer**

In mixers managing very viscous materials, it is essential to support
both tangential and oblique motion of the substance. The geometry and
profile of the sigma blade is intended such that the glutinous mass of
substance is pull, shear, dense, knead, and fold by the exploit of the
blade next to the walls of the mixer trough. The amount to which this
happen depends on the exploit of the blades - peripheral or overlap and
the ratio of the speed of replacement of the blades. The twist angle of
the blade can be customized depending on the necessary shearing.

**Operation of Sigma Blade Mixer**

In process, substance is loaded from side to side the top of the
container to characteristically 40 to 65 percent of the mixer\'s total
volumetric capability. The replacement of the blades is through serious
duty drive system characteristically consisting of a motor, gearbox,
coupling, and gears. The tip haste of the sigma blender is normally
incomplete to 60 metres per minute. Mixing may be approved out at
ambient temperature or under unnatural temperature situation. The
blender trough can be providing with jackets for transmission of hot or
cold media to continue the obligatory temperature situation within the
mixer. The release of the material from the blender container is also by
leaning of the mixer or from side to side an extruder / screw positioned
in the lower segment between the two trough compartments. The mixer may
be capable of with some one of these free activities.

The orientated discharge understanding is mainly common. The tilting
understanding of the container may be intended for physical process or
may be developed using mechanical or hydraulic understanding. Materials
of inferior thickness, the base free valve may be providing on the
blender trough. Intend outline of the valve should be flush with the
blender furrow to keep left from any dead or straight pockets of
substance).

The extruder/screw release has a benefit that supplies can be straight
discharge, extruded, in the obligatory shape or size for additional
dispensation. In adding, the screw intends eliminate operative
experience to hot materials if the integration process are approved out
at high temperature and/or with supplies that are toxic in character.

**Video link for visualization:**