Types, Uses, Features and Benefits of Blenders

Industrial Blenders: Types, Uses, Features and Benefits

Introduction

This article has everything you will want to know about industrial blenders and their use.

You will learn:

What is an Industrial Blender
Types of Industrial Blenders
The Difference Between Blenders and Mixers
How Industrial Blenders are Made
Uses for Industrial Blenders
Material Blended in an Industrial Blender
And much more��

Chapter One �� What is an Industrial Blender?

An industrial blender is a large-scale equipment specifically designed to mix and unify diverse manufacturing materials within a sizable containment. These devices are prized for their capability to effectively blend materials and facilitate reactions between them, making them ideal for a vast array of industrial purposes. Their significant capacity and cost-efficient operation are primary factors in their widespread use in various mixing processes.

Industrial blenders are frequently employed in scientific applications that necessitate the precise mixing of chemicals and pharmaceuticals. Their competence in providing exact measurements and uniform results makes them indispensable for accurately combining substances, often utilizing advanced PLC programming to modulate the mixing process.

Considering their usage, blenders are generally manufactured from stainless steel. Nevertheless, in scenarios where stringent sanitation is not essential, they can also be produced using materials such as steel, cast iron, or aluminum.

Chapter Two �� What are the types of Industrial Blenders?

A diverse range of industrial blenders is available, each tailored and crafted to suit specific industrial mixing applications. These industrial blenders and mixers are capable of blending a wide variety of materials, including solids, liquids, powders, granules, viscous pastes, abrasive substances, and even stones. Choosing the most suitable industrial blender can greatly impact process efficiency, production consistency, and product quality across numerous industries such as food processing, pharmaceuticals, chemicals, construction, plastics, and cosmetics.

Selecting the right industrial blender is crucial to ensuring it is well-suited for the specific materials being processed and meets industry requirements for scale, consistency, and throughput. With a broad spectrum of industrial blender types and designs available, from batch blenders to continuous mixing systems, finding an industrial blender that perfectly aligns with the requirements of a particular industrial task—whether it involves dry mixing, liquid blending, dispersion, emulsification, or homogenization—is achievable with a careful evaluation of process needs and desired blending outcomes.

Industrial Blender Types

Agitator Blender

Agitator industrial blenders offer continuous mixing for liquids through constant motion. This method relies on non-specific movements to blend materials, using rotating paddles or impellers for fluid agitation. While they are primarily designed for low-viscosity materials, such as liquid solutions or light slurries, they can be adapted with sturdier paddles or upgraded motor power to handle high-viscosity substances and more demanding industrial mixing processes effectively. Agitator blenders are commonly found in food processing, beverage, paint, and chemical manufacturing environments where uniform liquid mixing is required.

Paddle Mixer

A paddle mixer is a form of agitator, specifically designed for the blending of dry bulk materials and powders. Paddle blenders are used for gentle applications such as coating nuts, blending salads, mixing pharmaceutical powders, or creating wet slurries for food or chemical processes. They can also be engineered for thermal applications, such as cooking and blending simultaneously. The sizes of paddle blenders vary between 5 cu ft and 500 cu ft, offering flexibility for both small-batch and large-scale industrial mixing.

A paddle blender operates with paddles affixed to a central shaft, which stir the materials in a tumbling or folding action to ensure thorough and gentle mixing. These blenders may feature a discharge valve at the base or a tilting mechanism to release the blended contents, optimizing batch changeover and reducing waste. They operate at slower speeds to protect particle integrity and ensure a uniform and consistent mixture, making them suitable for industries like food processing, nutraceuticals, chemicals, and animal feed production.

Emulsifiers

The purpose of an emulsifier is to mix immiscible substances that are resistant to being mixed, such as water and oil. The emulsification process applies pressure to the substances, forcing them through filters or perforated plates to break down the molecular structure of the materials such that large molecules are made smaller and can combine more effectively. Emulsifier blenders are essential for producing stable emulsions in products like mayonnaise, creams, lotions, dressings, and industrial chemical formulations.

To improve the blending process of tougher or heterogeneous materials, an emulsifying agent can be introduced into the mixture. Unlike traditional blenders with blades, emulsifiers utilize specialized mixing chambers, high-shear heads, or pipelines through which the materials pass, allowing them to pre-mix and rapidly achieve a uniform, smooth consistency before the actual blending occurs. Industries such as cosmetics, pharmaceuticals, food, and chemical processing depend on industrial emulsifier mixers for product stability and quality.

Dual Shaft Blender

Dual shaft blenders feature two adjacent tubs, each containing a centrally positioned shaft. The shafts may be powered by a single motor using a crossover drive or by separate motors for each shaft. These shafts can rotate in various directions—parallel, opposing, or reversing. Depending on their spacing, the shafts can be positioned close enough to draw material from one another or set farther apart to avoid contact.

With dual motors, a dual shaft blender can operate the shafts at different speeds or in opposite directions, offering versatile industrial mixing capabilities. These blenders can be equipped with either ribbon or blade mixing elements, similar to those used in other commercial blender models. Dual shaft blenders are highly valued in processing applications that require thorough dispersion and uniformity of high-viscosity materials, adhesives, and pastes.

Ribbon Blenders

Ribbon blenders feature elongated, ribbon-shaped blades designed for mixing solid materials. These blades rotate around a central axis, and their distinctive ribbon-like shape is where the blender gets its name. Ribbon blenders are particularly effective at breaking up lumps in liquids that have been stored for a period.

The helical mixing tool, which occupies the entire mixing shaft, generates a spiral flow within the mixing chamber. Ribbon blenders are versatile, capable of mixing a range of materials such as powders, pellets, flakes, granules, pastes, slurries, and dough. The spiral motion of the helical blades produces a three-dimensional flow pattern, with material moving upward along the outer edges and downward in the center. Industries such as food, pharmaceuticals, chemicals, and plastics use ribbon blenders for dry blending, rehydration, and batch processing due to their high efficiency and scalability.

Rotary Blenders

Rotary blenders, also known as rotary drum blenders, lack traditional blades or paddles inside. Instead, the interior of the rotating drum features welded baffles or lifting scoops, which eliminates the need for moving parts within the mixer. This design ensures a gentle mixing action that avoids shearing or damaging sensitive materials and is ideal for fragile products and bulk powders.

The mixing blades in a rotary blender create a fluidizing effect with each rotation, effectively blending bulk materials and keeping product degradation minimal. This unique motion allows for rapid and efficient mixing of a diverse range of bulk substances, such as seeds, grains, dietary supplements, minerals, and additives, making rotary blenders an excellent choice for industries that require homogeneous batch blending with minimal fines or heat generation.

Double Cone Blender

A double cone blender, also known as a tumble blender, rotates to mix materials and is designed with a compact footprint, requiring minimal installation space. As the cones rotate, the contents gradually move to the bottom of the vessel, facilitating uniform mixing through a rolling and cascading action. These blenders feature an access cover for easy cleaning and inspection, meeting stringent sanitary and validation standards in regulated industries. Utilizing the free flow method, double cone blenders provide gentle yet highly effective blending of granules and powders, with the capacity to mix up to five different ingredients simultaneously. This makes them ideal for pharmaceutical, food, and metal powder processing where cross-contamination and batch integrity are critical.

V Shaped Blender

The V-shaped blender, also known as a twin shell blender or V-cone blender, uses rotation to tumble materials within its unique metal V structure. As the V rotates, materials are divided between its two wings and then blend back together. The wings are welded at angles of either 75° or 90°, optimizing the blend. This type of blender operates without internal moving parts and achieves efficient, reproducible blending with minimal rotations, making the process quicker compared to other industrial blenders.

Similar to double cone blenders, V-shaped blenders are well-suited for mixing free-flowing powders and bulk solid materials. The two openings are positioned at the top of each wing, facilitating easy discharge of blended materials and fast batch turnaround. V blenders are frequently used in the pharmaceutical, nutraceutical, chemical, and food industries for blending powdered ingredients, ensuring high-level mixing uniformity and containment.

Vibrational Blenders

Vibrational blenders utilize ultrasonic sound waves to mix fine powders and achieve homogenization. This process is akin to that of an emulsifier, but instead of relying on pressure to blend and reduce liquids, vibrational blenders use ultrasonic waves to generate shearing forces at a microscopic level.

Ultrasonic waves passing through a liquid or slurry create vacuum bubbles or voids in a phenomenon known as ultrasonic cavitation. These bubbles expand under continuous wave exposure but eventually collapse when they can no longer absorb energy. This intense, localized energy release enables fine particle dispersion throughout the liquid medium.

Vibration blending offers precise process control over various aspects of the blending operation, including the amplitude, frequency, and duration of the ultrasonic waves. Industries such as pharmaceuticals, nanotechnology, electronics, and advanced materials use vibrational blenders for particle size reduction, emulsification, and even cell disruption.

Homogenizer Blender

A homogenizer blender operates similarly to an emulsifier by breaking down unlike and unmixable substances, but with an emphasis on creating extremely fine particle size distribution. Homogenizer mixers use high shear force, pressure, and often ultrasonic or mechanical energy to reduce particle or droplet size, producing smooth, stable, and uniformly consistent compounds. This makes homogenizer blenders an excellent method for blending and processing products that require intensive mixing—such as dairy products, creams, beverages, pharmaceuticals, and cosmetics. Various methods are used by a homogenizer, including ultrasound, high-pressure processing, and rotor-stator blending technologies.

Vacuum Blenders

Vacuum blenders come in both horizontal and vertical configurations and are essential for sensitive or oxygen-reactive blending applications. They utilize a combination of heat and internal vacuum pressure to mix materials effectively while simultaneously removing air and minimizing oxidation or contamination. Additionally, vacuum blenders can also function as vacuum dryers during the blending process, making them valuable in industries such as pharmaceuticals, food processing, and specialty chemicals. The design of a vacuum blender mirrors that of a traditional mixer but incorporates a dedicated vacuum pump connected to an airtight blending chamber.

The vacuum pump removes air from the chamber, creating a low-oxygen, controlled environment in which blending can occur. This is especially beneficial for processes requiring the prevention of aeration, foaming, or microbial growth, and for those requiring residual moisture removal for downstream processing.

Mass Blender

A mass blender features a cabin that rotates on a horizontal plane, similar in design to a rotary blender, with blades or lifting bars welded to the interior sides of the chamber. These blenders are ideal for handling lumpy and dry materials, as well as small granular substances or abrasive powders. Mass blenders are available in models with capacities ranging from 50kg to 150kg and are widely used in industries such as construction, ceramics, and powder metallurgy due to their efficient handling of dense, heavy duty materials.

Octagonal Blender

Featuring an octagonal design with polygonal top and bottom sections, an octagonal blender is equipped with internal baffles that facilitate efficient and effective mixing. It is particularly well-suited for gently blending powders and granular materials without generating excessive dust or heat. To achieve optimal performance and homogeneous blending results, the blender should be filled to approximately 70% of its total capacity. This prevents insufficient mixing or product layering.

The superior blending performance of an octagonal blender is attributed to both its slow rotational speed and its unique octagonal chamber shape. This design enables materials to converge from all sides, minimizing the need for high RPMs and preventing product damage. The gentle, continuous tumbling cycle ensures that materials remain in consistent motion, resulting in highly efficient batch blending processes for pharmaceutical, chemical, and nutraceutical industries where blending accuracy and contamination prevention are essential.

Twin Screw Low Pressure Extruder

Twin screw low pressure extruders (TSE) are advanced mixers known for their intense, thorough mixing capabilities. Unlike standard extruders, TSEs feature two interlocking screws that enhance mixing efficiency at lower temperatures, which is valuable for shear-sensitive or heat-sensitive formulations. They are often employed in continuous processing lines, allowing for portioning, compounding, and intense premixing before materials are transferred to a high-pressure extruder for shaping or further processing.

Twin screw low pressure extruders (TSEs) provide a more intense and aggressive mixing process compared to standard blending techniques. They feature a high solids loading ratio, which denotes the proportion of solid material within the liquid mix, making them crucial for polymer compounding, plastics manufacturing, food extrusion, and chemical process industries where uniform dispersion of additives, fillers, or colorants is required.

Twin Screws of a Twin Screw Low Pressure Extruder

Static Mixers

are used to continuously blend fluids and materials in flow streams using stationary, rigid mixing elements placed in a pipeline with flanged connections at either end for secure installation. These passive mixing devices are constructed using baffles or structured elements, which are made of plastic or metal.

In static mixers, the flow stream itself drives the mixing process because there are no moving parts involved. The number of mixing elements can range from one to four, or more, based on the application's requirements and target mixing intensity. Additional elements can be incorporated as needed to enhance the mixing efficiency in challenging environments or for high-viscosity fluids.

Static mixers are commonly employed in shell and tube heat exchangers to improve heat transfer efficiency and in process pipelines for inline blending, dilution, and chemical dosing. They offer a cost-effective, maintenance-free solution for enhancing heat transfer, homogeneity, and product quality by affecting the film or wall coefficients, thereby optimizing thermal performance in industries such as water treatment, oil & gas, food and beverage, and chemical processing.

Vertical Blenders

Vertical blenders are well-suited for shear-sensitive materials, fine powders, and situations where floor space is limited. They feature a slowly rotating blending screw or auger, which is gentler compared to horizontal blenders and ideal for delicate or friable products. The screw spirals through the conical chamber, gently lifting material upward. When the material reaches the top of the cone, it falls back through the center to the bottom, ensuring thorough, even blending and excellent mixing accuracy.

The screw in a vertical blender is a contra-rotating helical ribbon that generates four cross flows: three driven by forced movement and one by gravity. An upward flow pushes material along the chamber's periphery while gravity causes it to fall in the center. The slow rotation speed and enclosed design of vertical blenders make them suitable for use in hazardous environments, dust-sensitive applications, and product containment processing. Power for the screw is provided by a gearmotor with a right-angle axis, ensuring consistent blending and efficient output from the kinematic chain.

The innovative design and high efficiency of a vertical blender enables it to handle a variety of batch sizes, starting at just 10% of its total capacity. Once blending is complete, the materials can be easily discharged through a valve located at the bottom of the conical chamber. Vertical blenders are favored in the pharmaceutical, chemical, and food industries for precise batch processing, reduced cleaning time, and compact installation requirements.

Leading Manufacturers and Suppliers

Chapter Three �� How Industrial Blenders are Made?

Each type of blender is crafted through a manufacturing process tailored to its specific shape, size, and the materials it will handle. Commonly made from steel, stainless steel, aluminum, or cast iron, stainless steel is the most frequently used material. The construction of each blender is meticulously designed to meet the industry standards for its intended application.

Blenders are extensively used in industries such as pharmaceuticals, plastics, and food production. A crucial feature of a blender is its seal, which prevents material leakage and waste. This necessitates precise engineering of all hatches, valves, and other openings in the blender's design to ensure effective containment.

Making Industrial Blenders

Metals Used

Stainless steel is the standard material for industrial blenders used in the food and beverage, cosmetics, and pharmaceutical industries due to its hygiene requirements. In applications where hygiene is less critical, blenders may be constructed from steel, cast iron, or aluminum.

Roll Forming

After selecting the metal type, the metal is roll-formed using a twin roller press. The metal sheet is repeatedly passed through the rollers until it is shaped into a "U" configuration.

End Plate

The "U"-shaped metal piece is welded to the end plate of the blender. Spot welding is used to secure it to the plate, with the weld applied horizontally where the curved sheet meets the end plate.

The image below illustrates how the curved sheet is spot-welded perpendicularly to the end plate.

Paddles for Blenders

The paddles for most blenders are made out of stainless steel. They are produced using a variety of methods that cut the shapes of the paddles from a plate of stainless steel. Each manufacturer has their own process for cutting the paddles using a variety of techniques.

One technique for cutting paddles involves using a plasma cutter, which provides precise cuts to the desired size and shape. The heat generated by the cutter ensures accurate lines and angles.

After the paddles are cut and shaped, they are curved in a press to enhance their ability to lift, blend, and scoop materials effectively.

Main Shaft

The main shaft of the blender plays a crucial role in the blending process. It provides the rotational force needed to drive the paddle assembly and must endure high temperatures. Smaller diameter shafts experience higher stress compared to larger ones. To ensure the shaft operates within its stress limits and avoids fatigue failure, larger diameter shafts are preferred over smaller ones.

A key seat is machined into the end of the shaft to securely connect it to the mixer's main drive box.

Blender Arms

To secure the paddles within the mixing chamber, arms are firmly bolted to the shaft. These arms feature holes that accommodate the paddles and permit adjustment of clearance. Both the arms and paddles are positioned at an angle, and the spacing between the paddles and the chamber walls is meticulously verified to ensure proper clearance.

In certain instances, the arms, paddles, and shaft are welded together to form a solid unit. After welding, the connections are ground smooth to produce a uniform shape. This method provides a more secure and integrated connection between the internal components of the blender.

Welded units are favored in food and chemical processing due to their ease of cleaning.

Arms, Paddles, and Shaft of a Paddle Blender

Blender Motor

The motor is mounted on the blender, with the drive assembly linked to the agitator shaft. A taper bushing ensures that the drive gear box is properly centered on the shaft.

Covers and Safety Grids

Horizontal blenders, the most commonly used type, feature covers on the top of the chamber for access. These covers are equipped with safety grids to protect operators from large materials when the blender is open. The covers and safety grids allow for loading, unloading, and inspecting the paddles and shaft.

After installing the covers and grids, additional monitoring devices are added, including air pressure valves to regulate the air pressure along the shaft.

Control Panel

Control panels vary depending on the material and type of blender. They are designed to simplify the operation of the blender by minimizing the required input. Programmable Logic Controllers (PLCs) are essential in modern industrial blenders, offering multiple user interfaces. PLCs need to be custom-programmed to handle specific requirements such as weight, time, speed, and other parameters.

Typically, PLCs for blenders are custom-built from the ground up, incorporating the necessary adjustments and data for specific applications.

Chapter Four �� What are the uses of Industrial Blenders?

Industrial blenders are crucial in manufacturing due to their large capacity, allowing for the formulation of products in substantial quantities. They enable the production of final mixtures in bulk, ensuring an efficient and seamless blending process that supports smooth and worry-free production.

Blenders are used globally across various industries to combine components and create products. Whether it's mixing ingredients for bread or blending polymers for plastic goods, blenders play a crucial role in completing the production process.

Industrial Blender Uses

Pharmaceuticals Uses

Pharmaceutical manufacturing demands equipment that ensures exceptional accuracy, consistency, cleanliness, and efficiency. Regulatory standards are in place to guarantee the safety and purity of medications for public use. Consequently, blenders used in the pharmaceutical industry are highly specialized and intricate to meet these stringent requirements.

Blenders in the pharmaceutical industry are used for preparing emulsions, reducing particle size, facilitating chemical reactions, altering material flow, and dissolving components. Due to the complex requirements of this industry, a variety of blending devices are employed to meet diverse needs.

Adhesives

The effectiveness of adhesive production hinges significantly on the blending process. Whether it’s homogenizing or dissolving, the type, size, and blending method play crucial roles in determining the efficiency and quality of the adhesive. Advances in blender technology have greatly enhanced the blending of adhesive materials, leading to improved product performance and application.

Adhesives that are produced using an industrial blender include epoxies, latex sealants, joint compounds, polybutene emulsions, polyurethane, and rubber cement, to name a few.

Uses in Food

When people hear the term "blender," they often think of the countertop appliance used for making food at home. However, in the food industry, blenders are employed on a much larger scale. They are utilized for a variety of processes, including dry blending, emulsification, dissolution, dispersion, and the blending of highly viscous ingredients.

Blending plays a crucial role in converting raw ingredients into delicious and ready-to-eat food products. An industrial blender’s precision ensures the ideal texture and appearance for each product. With a range of available blenders, processors can choose smaller units for small-scale operations or larger, more durable machines for extended production runs.

Plastics Uses

In the plastics industry, blenders are essential for determining the type, strength, and molecular structure of plastics. The initial step in plastic production involves blending various polymers and chemical additives into a solid mixture. This critical process directly impacts the quality, design, and functionality of the final plastic material.

Cosmetics Industry

In the cosmetics industry, a significant challenge is blending materials that are not naturally compatible, which often involves emulsifying them to break down their molecular structures. Industrial blenders provide superior control and accuracy, allowing producers to blend these materials effectively without compromising their essential qualities.

The cosmetic industry demands blenders that can adapt to various consistencies, viscosities, and shearing requirements of different cosmetic materials. Industrial blenders are well-suited to meet these challenges effectively.

Others Industries

The industries described above represent just a few of the many that depend on industrial blenders for their processes. Any production process that involves the blending and mixing of various materials relies on industrial blenders to emulsify, blend, mix, and pulverize raw materials effectively.

Industries and Their Blenders
Aerospace	Candle Waxes
Aviation	Synthetic Leather
Batteries	Tobacco Products
Electronics	Cements
Cannabis	Ceramic
CBD Manufacturing	Metals
Chemicals	Inks
Glass	Paints
Pet Health Applications	Coatings

Chapter Five �� What types of materials are blended in industrial blenders?

Industrial blenders are versatile and can handle a diverse array of substances, including pellets, rocks, viscous fluids, and powders. Their robust construction, long-lasting performance, and dependable quality ensure they can effectively process any material with resilience and durability.

Industrial blenders boast a high tensile strength steel construction, which allows them to handle a wide variety of materials with minimal restrictions. This durability makes them essential tools in material processing and production.

Materials Blended in Industrial Blenders

Dry Solids

When mixing dry powders, no liquids or water are added to ease the material for the blender. In the food sector, dry powders include coffee grounds, baking mixes, flavorings, spices, flour, tea leaves, and frozen goods. In the chemical sector, dry powders encompass powdered soaps, custom chemicals, ceramics, and plant nutrients.

Dressings and Spreads

Blending dressings and spreads with precision demands careful attention and thorough planning, as improper mixing can compromise the flavor and quality of the end product. The challenge is heightened by using oil as the primary ingredient. This process is time-consuming and typically does not involve the use of blades or mixers.

Pet Foods

Dry pet food undergoes a blending procedure designed to create a solid texture that fractures and crumbles when chewed. An industrial blender refines and optimizes the texture, shape, and composition of the dry pet food.

Sauces

Among all food products, sauces present the greatest challenge to prepare due to the need for exact blending of precisely measured ingredients. Blending too rapidly can lead to a sour taste, while blending too slowly may result in an incorrect consistency. Advanced PLC control in industrial blenders helps achieve the perfect sauce by managing the blending process effectively.

Confections

Creating confections involves a blending process similar to that of sauces, demanding the same level of precision. Traditionally, candies and sweets were crafted by hand on large heated surfaces, requiring extensive time for forming, churning, and shaping to achieve the right consistency. Today, industrial blenders have significantly reduced this time, allowing for the efficient preparation of large batches with the desired consistency in much less time.

Bases

Preparing bases requires meticulous attention and considerable patience. Sometimes, chefs keep the ingredients and their proportions secret. Industrial blenders are perfect for creating these confidential bases, as they ensure precise ingredient ratios and allow for optimal blending speed and duration.

Syrups

Syrups are created by mixing preservatives with raw sweeteners in water. This process often involves vigorous blending using fast-moving paddles and agitators. A key aspect of this blending is the shearing of the ingredients to ensure thorough dissolution.

Polymers

Polymer blending involves combining different polymers without the need for bonding agents. This method aims to quickly and cost-effectively produce materials with unique and complex properties. The resulting blended polymers often exhibit enhanced characteristics compared to the individual polymers, leveraging the strengths of both to create superior materials.

In industrial polymer blending, a significant challenge is ensuring the miscibility of the polymers. The process often necessitates intense pulverization to break down the molecular structures of the materials, facilitating their effective blending.

Metals

Metal blending occurs when metals are reduced to a powder form. The particle size and shape influence the blending method chosen for their combination. This process results in a material that harnesses the properties and benefits of each metal. By breaking down the metals' molecular structures, the blending creates a unified substance with enhanced characteristics.

Conclusion

An industrial blender is a machine used for large-scale production that consists of a large tank capable of mixing and blending batches of manufacturing materials to create a reaction between the materials.
The precision and accuracy of industrial blenders make them ideal for combining chemicals in the exact required amounts using the blender’s PLC programming.
There is a wide assortment of types of industrial blenders that are specifically designed and engineered to meet the needs of specialized applications. Industrial blenders blend solids, liquids, and various mixtures such as granules, powders, sticky pastes, abrasive matter, and stones.
Every type of blender is produced using a manufacturing process that is designed for its shape, size, and the materials that will be blended.
The main reason industrial blenders are an essential part of manufacturing production is their large capacity. Products can be formulated and devised with upscaled proportions that can produce the final mixture in large quantities.