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  • MIP Process Corporation
  • MIP Process Corporation
  • MIP Process Corporation
  • MIP Process Corporation
  • MIP Process Corporation

Products and Services

Thickening and Clarification

Introduction

Thickeners are used in continuous process applications where liquid-solid separation by sedimentation is involved. Thickeners have three  basic purposes:

  • Concentration, or raising the density of a mixture of solids and liquids (feed slurry).
  • Clarification, which involves removing solids from the mixture.
  • Hydro-separation, where a specific fraction of solids is removed from a mixture.

In some applications, thickeners recover valuable solids whereas valuable liquids are recovered in others.  In addition, thickeners are an economic means for of process waters. Clarifiers are extremely efficient for treatment of waters.

MIP Process Technologies thickeners consist of the following basic parts, each of which is supplied in a number of variations to best suit a particular application:

  • Tank
  • Drive unit and optional lifting device
  • Torque Tube (centre shaft)
  • Rake arms and blades
  • Bridge
  • Underflow discharge arrangement
  • Dual feedwell
  • Overflow launders with weirs
  • Instrumentation

Thickener development and general history

Sedimentation technology was originally developed in the mining industry.  Prior to the development of the continuous thickener, batch gravitational settling was employed. In such batch operations, dilute feed was pumped into a tank continuously until a clear overflow was no longer obtained. The feed was discontinued and the tank left undisturbed until the solids had settled. After a suitable retention time, clear supernate liquor was decanted and the thickened sludge removed.

After using batch-settling operations for some time, the industry developed cone settlers that could be operated continuously.  This was done by pumping a continuous feed stream to the settling cone, removing underflow sludge continuously from the bottom of the cone and overflow continuously from launders at the surface on the periphery of the cone. However, to maintain a uniform underflow zone in the cone, and to ensure proper removal of the solids, the angle of the cone was steep thus limiting the diameter of the unit from a practical height standpoint.

Since the capacity of gravitational settling equipment was found largely to be a function of the cross-sectional area, it was evident that application of the settling cone was limited. As larger units were developed to handle higher capacities, it was found that mechanisms were required to move the underflow or sludge to a common underflow point. This led to the development of the continuous thickener in its present day configuration in 1905.

The use of continuous thickeners rapidly expanded to the chemical, sanitary and water treatment industries.

Thickener Operation

During thickener operation, feed enters the feedwell, via a feed pipe or open launder.  In order to promote settling, it is increasing to dissipate this energy.  In some cases, flocculants or coagulants are added to the feed to agglomerate particles and improve settling. Feed dilution may also take place.

After passing through the feedwell, the feed enters the main portion of the tank where settling occurs.  A deflector plate attached to the torque tube may be installed to assist with the slurry distribution over a greater area of the tank. Raking arms attached to the centre shaft and drive rotate to direct the settled solids to the discharge cone from which thickened slurry is pumped out of the unit. The following paragraphs will explain the main thickener parts in more detail.

Tank

The tank is constructed from a variety of materials, the most common being mild steel and concrete.  Tanks may be supported on legs, giving access to the underflow pumps and valves, or supported by the ground on compacted soil support and access gained via a tunnel. MIP’s tank design provides for a scalloped bottom mild steel tank design.

Thickener Mechanism

The mechanism consists of the drive with an optional lifting device, torque tube, rake arms, blades and bridge.

MIP drive heads consist of a multi-stage planetary gearbox, hydraulic drive unit, and an optional lifting device.

Lifting Device

This is used to raise the rakes above the mud bed, if the solids are not being removed from the thickener quickly enough. It promotes dependable, continuous operation by providing adequate lift to raise the raking arms out of the compacted or heavy solids zone during thickener upset conditions.

Lifting devices allow rake mechanisms to rotate while the assemblies are raised or lowered. Hydraulic lifting devices have replaced manual or motorized mechanical screw devices.

Torque Tube

This is typically a thick walled pipe or cage that transfers the rotation of the mechanism to the rakes.

Rakes

The rakes convey underflow sludge to the discharge point and thicken the sludge by creating paths in the compressed zone, which allows escape of entrapped liquid upwards.

High Rate Thickeners

Perhaps the most significant design optimisation effort in thickening in the last twenty years has been in developing ways to more effectively use the horizontal cross sectional area of the thickener. The introduction of polymeric flocculants gave an impetus to development of High Rate Thickeners. The result is now common use of the term “High Rate Thickener” which has been applied in all areas of industry.

The characteristic features of a High Rate Thickener, which distinguishes it from a Conventional Thickener, are:

  • Deeper feedwell
  • De-aeration of the feed (either internally in the thickener or external  to it)
  • A means of deflecting the feed from the vertical & distributing it within the body of the thickener
  • Controlled bed level

High Rate Thickening is a process whereby mineral particles are flocculated, thoroughly mixed within a feedwell and then injected uniformly into a hindered settling zone in the thickener with largely radial motion. A pre formed hindered settling zone allows horizontal distribution of incoming feed into the settling bed which, at the point of injection, is in a fluidised state. The radial motion of the feed directs the solids across the thickener, thereby utilising the entire thickener surface area for further settling. Furthermore, the injection of solids into the fluidised bed assists in the capture of fine particles, which prevents them from escaping to the overflow. The hindered zone therefore also acts as a “filter” for improving overflow clarity.

A clear interface is formed at the top of fluidised bed and this can be accurately monitored for effective thickener control.

Clarifiers

The design of clarifiers focuses on minimizing solids escape in the overflow liquor stream and effective solids settling and removal.

MIP Design Considerations

Thickeners and clarifiers are operating in the minerals processing, chemical water treatment, industrial and effluent treatment throughout the world.  In addition to this existing technology, MIP Process Technologies (Pty) Limited brings customized and tailor-made process solutions.

In our design, we consider not only your process data, but also the long-term mechanical performance, maximum circuit efficiency, availability and minimized operating costs.

Some of our design considerations include:

  • Precise sizing for the duty
  • High torque planetary gearbox
  • Accurate torque measurement including a “high torque” audible and visual alarm with “over torque trip” for mechanism protection in the event of ultra high torque conditions
  • High efficiency feedwell – adjustable feed dilution system
  • Ability to monitor and/or operate via Scada, if so desired
  • Multiple Flocculant addition points for easy optimization
  • Full span walkway for dual emergency exits and to allow easy access.

Effect of Feed Dilution

The introduction of clear supernatant into the feedwell dilutes the pulp and thus lessens the effects of hindered settling.  The graph below reflects this relationship and higher settlement rates are achieved with the lower feed concentration.

MIP Process - Effect of  Feed Dilution

Design Criteria

In order to ensure we provide the best technical solution, each thickener is custom designed for a specific application.

Typically, the tank is modeled with finite elements and the sub-structure and the bridge with beam elements.  This modeling has resulted in MIP being able to optimize designs and provide the most cost effective solutions.

Click image below to enlarge

Special attention is given to the design of the thickener feedwell (for high efficiency) and specially profiled rake blades for maximum transfer of viscous and heavy material at minimal torque consumption.

As part of its development initiatives, MIP Process Technologies (Pty) Limited has committed itself to ongoing test work and research in order to improve our competitive technology and to be ahead of our competitors.

Attrition Scrubbers

The MIP Process Technologies (Pty) Limited attrition scrubber is a culmination of more than fifteen (15) years of experience in this field.

The attrition scrubber operates on the principle of creating more attritioning zones within the machine. Our unit is designed with multiple blades, instead of only two, thus creating numerous attritioning zones, ensuring that every particle passes through the working area. This offers multiple opportunities for particles to achieve more than adequate scrubbing.

Features and benefits of our attrition scrubber include:

  • Design specific
  • Low capital and operating costs
  • Low power consumption
  • Minimal wear
  • Low maintenance
  • Cost effective and easy to operate
  • Work achieved
  • Different tank designs

Each attrition cell is fully rubber-lined in accordance with the client’s specifications for wear resistance.  The unit is designed specifically for the required duty with replaceable rubber lining in the high wear areas and ease of maintenance.

All the cells are manufactured from mild steel and each attrition cell has its own mechanism.  Materials of construction are of the highest quality available.  MIP Process Technologies (Pty) Limited boasts the best workmanship and most modern practices.

Flocculant Make-Up Plants

The MIP Process Technologies (Pty) Limited Flocculant make-up plants are of a modular design and they can be supplied as an integral packaged unit.  The air drying process allows pneumatic conveying of dry Flocculant powder to be deposited to a remote system, e.g. the top of a thickener.

We employ high shear attritioning of the newly wetted discreet Flocculant particles and gentle mixing of the wetted Flocculant for ageing.  There is no inter-stage pump between wetted Flocculant and storage, instead the Flocculant is transferred via a dart valve. Our Flocculant make-up utilizes static mixing of concentrate Flocculant and dilution water.

Horizontal Linear Screens

The MIP horizontal belt screens offer the following design features.

  • Pre-engineered units: proven short delivery times
  • No vibration: eliminating expensive support structure
  • Low noise levels: environmentally friendly
  • Range of screen apertures: process specific design
  • Low power consumption: low operating costs
  • High availabilities: minimal production losses
  • User friendly: ease of operation
  • Flexible: easy to change parameters

Slurry Samplers

Some of the simple basic rules of sampling are:

  • As a minimum, the cutter gap in a sampler cutter must be three times as big as the largest particle being sampled.
  • The sample cutter must move through the stream at a constant rate.
  • The maximum velocity of a sample cutter through a stream is 600mm/second.
  • More small cuts are preferable to one larger cut.
  • Sample must not be contaminated by splashing when the sampler is in the stationary position.

The MIP sampler is a strong robust machine that is based on tried and tested design principles that are proven to give years of reliable service.

A cross cut sampler runs horizontally and typically takes a cut through a slurry stream travelling in an open launder.

A rotary sampler takes a sample, typically in the vertical position, and is usually fitted to a vertical, non-pressurised, pipe.

The MIP Process slurry sampler range consists of the following ranges:

  • Primary Samplers – Cross-Cut
    • The MIP Automatic Cross-Cut Sampler is designed to operate as a primary sampler.
  • Rotary Samplers
    • The MIP Process systems' Rotary Samplers can be designed as Primary sampler or a continuous (secondary) vezin units.
  • Control Panel
    • The control panel is a minimum of an IP55 enclosure, and houses all of the necessary timers, switches and overloads.
  • Pressure Pipe Samplers
    • This in-line sampler can be installed in pipes from 50NB to 1000NB.
  • Fixed Cutter Samplers
    • These units are installed in launders to provide a continuous sample.

All samplers have been designed to require minimal maintenance and consists of a cylindrical enclosed steel housing with feed, discharge and sample ports. The housing is rubber lined for abrasion resistance, with the outer surfaces painted.

Mixers & Agitators

The following are some of the highlights of our principals, Chemineer Inc:

(a) Chemineer Inc. is an American based company established in 1952, and one of the largest mixer suppliers in the world. The Chemineer name is well known in many markets including chemical and petrochemical, mineral processing, food and beverage, water treatment, polymers, FGD/energy, biotechnology and pulp and paper.

(b) Some of the Chemineer “firsts” are:

  • The first static mixer – Kenics
  • The First to develop ChemScale, a tool to educate the industry and publish to users
  • The first to use Particle Image Velocimetry and Computational Fluid Mixing (CFM) to visualise flow patterns
  • The first expert design software, AgDesign
  • The first high-efficiency gas dispersion impellers: CD-6, BT-6
  • The First non-rotating agitator – Clean Sweep

(c) Chemineer Inc has a large installed base of mixers worldwide and a marked presence on the African continent as you will see from our reference list.

Chemineer make use of our proprietary gearbox that is specifically designed for mixer applications with larger output shaft and bearing.

Due to the efficiency of the HE-3 impeller a smaller motor size is required compared to traditional mixers.

Chemineer is well known in the following industries:

  • Mining and Minerals
  • Chemical and Petrochemical
  • Pharmaceutical
  • Biotechnology
  • Polymers
  • Food and Grain Processing

Moyno Progressive Cavity Pumps

Moyno, Incorporated is a leading manufacturer and marketer of Moyno® progressing cavity pumps, sludge pumps, metering pumps, sanitary pumps, multiphase fluids transfer systems, grinders and controls. The company has an extensive worldwide stocking distribution network that serves a wide range of industries including water and wastewater treatment, pulp and paper, specialty chemical, food and beverage, pharmaceutical, mining, petrochemical, and oil and gas transfer.

Water Treatment

MIP Process Technologies (Pty) Ltd has a division that specializes in waste water treatment and water reclamation.

MIP and Chemineer brings proven technical expertise to each mixing solution, from basic mixer and impeller design through complex process application analysis.

Our high-tech customer test lab offers the most advanced testing techniques in the industry. Combined with proprietary data evaluation methodology and extensive field experience, Chemineer and MIP provides the most accurate water and wastewater treatment application evaluation possible. These tools and procedures include:

  • Computational Fluid Dynamics (CFD) : provides visual projections of mixer performance in the mixing tank and generates a series of mathematical models of fluid flows.
  • Digital Particle Image Velocimetry (DPIV) : provides instantaneous flow visualization and quantitative measurement of the fluid velocity field in the mixing tank.
  • Laser Doppler Anemometry (LDA) : corroborates time averaged DPIV data, especially for velocity fields in the vicinity of the impeller.
  • Laser Induced Fluorescence (LIF) : enables the user to gain a fundamental understanding of mixing by tracking the path and diffusion of injectants in agitated vessels and static mixers.
  • CEDS® (Chemineer Expert Design System) : interprets process design data via laptop for on-site analysis, design and evaluation.
  • ChemScale® : the industry standard method for effective mixer selection that helps to optimize the solution for your specific process needs and meets “G” value requirements.

MIP Process provides expertise in the following areas:

  • Nitrification with Chemineer mixers
  • Anaerobic Digestion
  • Sludge conditioning
  • Carbon make-up and storage
  • Flocculation with MIP Flocculant Plants and Chemineer HEV mixers
  • Rapid/Flash mix