The Pioneer Pump® ElectricPAK™ delivers more than just a modular design that can arrive on site and startup quickly. It’s also engineered from the ground up to offer a fully streamlined experience for both owners and operators.From initial selection, to installation, to a lifetime of operation: durability and performance are built into every component. Each configured assembly includes high-performance pumps and electric motors that provide better flow, higher head and greater efficiency.

The Pioneer Pump® ElectricPAK™ delivers more than just allllllllmodular design that can arrive on-site and startup quickly.The Pioneer Pump® ElectricPAK™ delivers more than just aThe Pioneer Pump® ElectricPAK™ delivers more than just a modular design that can arrive on-site and startup quickly. It’s also engineered from the ground up to offer a fully streamlined experience for both owners and operators.From initial selection, to installation, to a lifetime of operation: durability and performance are built into every component. Each configured assembly includes high-performance pumps and electric motors that provide better flow, higher head and greater efficiency.modular design that can arrive on-site and startup quickly.It’s also engineered from the ground up tostreamlined experience for both owners and operators.From initial selection, to installation, to a lifetimeof operation: durability and performance are builtinto every component. Each configured assemblyincludes high-performance pumps and electricmotors that provide better flow, higherhead and greater efficiency.It’s also engineered from the ground up to offer a fullystreamlined experience for both owners and operators.From initial selection, to installation, to a lifetimeof operation: durability and performance are builtinto every component. Each configured assemblyincludes high-performance pumps and electricmotors that provide better flow, higherhead and greater efficiency.

Franklin Electric makes choosing the right products for your water system needs easy. We collaborate with you to determine the best product solution suited for your specific application requirements.

Increase efficiency, improve safety, and reduce downtime with the VDG Drum Motor. Customers and OEMs share their experiences upgrading their belt conveyors with our one-component drum motor.  The innovative VDG Drum Motor has all drive components including motor and gear reducer enclosed inside the drum for a safer, more efficient, and space optimized belt conveyor drive solution. Reducing energy expenses by 30% per drive, all components of the VDG Drum Motor are designed for 80,000 hours of continuous operation before maintenance, minimizing downtime, reducing maintenance costs, and increasing production.  All VDG Drum Motors are engineered and manufactured in-house in USA and Canada, using cutting-edge production technology and automation, ensuring quality, fast delivery, and after sales support.

All You Need To Know About Cage Mills Cage Mills have a high ratio of size reduction after a single pass through the cages. Here's why, and how. Hands down one of the most versatile size reduction machines and one of the hardest working is the cage mill. There are several varieties of cage mills, but their similarities are more numerous than their differences. They all are internally fed impactors that can crush, grind or pulverize many different materials to specified degrees of fineness. History By 1900, Nathan Stedman had built more than one hundred cage mills designed exclusively to crush coal. Soon other applications were discovered, leading to the increased use of cage mills for crushing such products as chemicals, clay and fertilizer materials. Multiple-row cage mills – two-, four- and six-row -- were commonplace. It was not until the 1930s that the true value of cage mills in the production of agricultural limestone and the crushing and beneficiation of stone and gravel was realized. Cage Mill Pulverizers The cage mill was so popular the Stedman Machine Company became part of farming vernacular -- farmers began referring to agricultural limestone as “Stedman Lime” due to the cage mill's unique capability to create the proper material fineness in just one pass through the crusher. Single-row cage mills were used extensively in the construction of the pioneered Pennsylvania Turnpike, primarily for the beneficiation of aggregates. Beneficiation is an elementary process, but it still is one of the most widely practiced applications of single-row cage mills. Gravel is passed through the mill and the softer, undesirable particles; -- breaking more readily than the harder ones; -- are screened or washed away, leaving a hard, high-quality aggregate. Versatility New uses are constantly being discovered for these versatile workhorses, but the nature of cage mills is such that improvements in them tend to be gradual and evolutionary instead of dramatic and revolutionary. The cage mill can be applied to effectively crush, grind and pulverize a broad array of abrasive and non-abrasive materials, including wet sticky types. The latest technology incorporated in these high-efficiency design mills insures greater crushing capacities, finer grinds and cleaner, safer operation. Fundamentally, cage mills are crushers capable of reducing or disintegrating many kinds of materials to small pieces. They reduce materials solely by impact and range in size from as small as 18 inches to as much as 72 inches in diameter. However, custom units may range as high as 96 inches in diameter. In general, the larger the mill, the lower the cost of operation when measured against tons of output. Operation Cage Mill Size Reduction Equipment A typical cage mill has only one part that moves - the rotor assembly. The material to be crushed is fed into the center of the rotor, or cage, through an intake hopper. The massive bars of the spinning cage aligned in rows strike the material and smash it into particles. The particles are then thrown against subsequent rows, other particles and the cage housing where they impact against breaker plates. Every impact - against cage bar, breaker plate or another particle - tends to reduce the original matter further, into more numerous and smaller pieces. By the time the material finally escapes from the cage mill, it has been thoroughly crushed. The major difference compared to other size reduction methods is the absence of close clearances between the crushing part and the breaker plates, allowing for less maintenance and higher efficiency of the machine. Also, they do not require grate bars as the principal source of impact in the cage mill are the pins of the revolving cages. Impact crushing, particularly impact crushing that uses the most suitable cage mill available, has a number of advantages over compression crushing. Cage mills produce a more cubical product of consistently high quality and they are capable of a very high ratio reduction. There is no decrease in quality of the product even after long periods of operation. Cage mills represent a lower initial investment than most other types of crushing equipment and maintenance is easy and inexpensive to perform. Application Cage Mill Manufacturer The wisest and most effective use of cage mills depends on a proper understanding of them, of how they are made and what they will and will not do. Multi-row mills typically consist of an even number of cages: two, four or six. The cages are arranged concentrically, with each row spinning in the opposite direction from that of the row adjacent to it. Two motors are required. They are mounted on opposing sides of the mill, where they turn in opposite directions. One, two or three rows may be mounted on each shaft. A multi-row cage mill utilizes multiple stages of selective impact reduction. The material to be reduced is fed into the center of the innermost cage, where it is struck by the massive spinning pins and distributed 360 degrees around the cage. Centrifugal force and the impact of the pins causes the material, now reduced to smaller pieces, to pass through the cage into the pins of the next row, which is spinning in the opposite direction. The farther away from the center cage the particles travel, the more their impact velocity is increased. In the process of being thrown from row to row the particles also strike each other. They finally are thrown against tough breaker plates that line the inside of the housing. After many violent strikes against the pins, the breaker plates and each other, the much-reduced particles are caught by the outer housing and allowed to drop through the discharge at the bottom of the housing. Size Control Properly presetting the speed of the cages allows the succeeding rows, moving from the innermost outward, to act principally on the particles that have not yet been reduced to the desired size. Particles that have been crushed sufficiently tend to pass through the subsequent rows without being materially affected. Thus, over crushing or under crushing is effectively controlled by adjusting the speed of the cages. All cage mills are fed internally - - the material to be crushed is dropped into a hopper, from which it travels by chute into the center of the innermost row. It falls from the chute onto the spinning pins of the cage, which strike the falling pieces of feed and explode them into many smaller pieces. The particles are propelled by centrifugal force from the innermost cage into the pins of the adjacent row, which is spinning in the opposite direction. Cage Mills for Aggregates Particles that are still too large are struck by the pins of the second row and reduced further. The reduction process continues through any additional rows that may be part of the machine. The impact velocity of the particles increases as the centrifugal force carries them outward from one cage to the next until they finally strike the mill housing and drop toward the large discharge opening at the bottom of the housing. Controlling the speed at which the cages revolve allows the operator to control the amount of reduction that takes place. That is, if the speed is properly preset and controlled, the material will be reduced to its desired size at some point during its trip through the cage mill and then virtually no further reduction will have to take place. The selective impact crushing that is a characteristic of cage mills minimizes the amount of oversize and undersize particles to be found in the finished product. The design of the cages controls the path that the material will flow through the machine. This makes it possible to concentrate the wear on the pins, which are made of very hard alloys to give maximum possible service before they have to be replaced.

How Much Does It Cost To Operate a Crusher? By Chris Nawalaniec Crushing equipment is the heart of an industrial material-processing system. The size reduction choice you make will have a profound impact on the profitability of your business. When the right choice is made, you should expect many years of profitable operation. How do you make the right crusher choice? Crushers are not glamourous. They are brute force workhorses and what they do is simple, really. Size-reduction equipment in all forms is adding energy to a material to make big pieces smaller. Simple, right? Cost versus Value What does it cost or what is it worth? Producers need to keep that simple equation in mind. We all have to keep our eye on the ball and stay focused on profitability. What are Crushing Costs? Capital acquisition cost Base machine Structures and chutes Motors, drives, guards Energy consumption per unit produced Electricity Compressed air Wear parts cost Normal maintenance Planned downtime Lubrication costs Oil Grease Major repairs Infrequent maintenance Unplanned downtime Labor Normal maintenance Special or unique tools required When the above costs are all accounted for, they are used to quantify the production costs related to size reduction and are expressed in cost per unit of measure production. For example, $0.50 per tph. What Does Value Mean? There are always opportunities to buy a machine at a lower upfront cost. This usually translates into paying higher operating costs over the life of the equipment. Higher service labor cost. Higher wear parts costs. Higher energy costs. Often there is a justifiable case to spend additional capital dollars for the better machine. When evaluating crushing equipment suppliers, crusher manufacturers should quantify both costs: purchase price and operating costs. Before you purchase, ask for reference customers to visit. Selecting Equipment Why are there so many types of equipment? Our team brainstormed this question, and we came up with more than 50 tools or machines that are used for size reduction. What we are addressing here is industrial size reduction of dry, solid materials, which are grown, mined or chemically synthesized, and need to have a physical dimension alteration to be put to use. Customers are asked five questions to begin the equipment selection process. What is the material? What is the moisture content? What is the maximum size going into the machine? What is the size range desired after crushing? What is the desired production rate of finished product? When it’s time to dive a bit deeper to define the problem, we ask some additional questions. How long do you expect to operate the plant? Are you looking at mobile, skid-mounted or fixed installation? Are there electrical limitations or special power requirements at the plant site? Is the system open or closed circuit? Do we need to consider future expansion plans now? The variables above all affect your costs. Let’s take the first question as an example. How long do you plan to operate? There are times when mines reserves, stockpiles, permits, project contract terms affect expected life. If a project is limited by any factor, then “good enough” could be the best choice. As long as the equipment is safe and there are machine wear parts and service available, then going “cheap” may be the best choice. Another factor to consider with low-cost is limited post-sale assistance if there is some process change or major equipment problem. You don’t want to be hung out to dry. Aggregate producers typically expect to be running and profitable for many years. Always buy a crusher from an established company, develop a relationship, and expect ongoing service and personal contact. Ask before you buy about how they approach post-sale parts sales and service. Ask the company quoting how they intend to offer service for their crusher. How many field service people do they have? Are they local, regional or too far away? Not having responsive suppliers will have a significant impact on your plant profitability. Summary Investing in the best size reduction equipment for your specific needs is a big decision. The above should give you a lot to think about so equipment solutions can be objectively analyzed. Chris Nawalaniec is vice president of sales and marketing at Stedman Machine Co.

U.S. Tsubaki DISCO is one of the most competitive traction drive units on the market today. DISCO combines compactness and simplicity with energy efficiency to ensure quiet operation and long, trouble-free performance. Starting with materials of the highest quality, U.S. Tsubaki carefully manufactures and assembles DISCO according to strict quality control and efficient manufacturing processes.

Van der Graaf is a leading designer and manufacturer of specially engineered drum motors. Built to endure the demands of the bulk handling industry – from ship loading, to power generation, to surface and underground mining. Van der Graaf products are manufactured and marketed worldwide through a respected international network of distributors. As the leading global supplier of conveyor belt drives, Van der Graaf has proven to be highly intuitive in projecting and reacting to changing market demands. The Extreme Duty Series offers a conveyor drive in which all components are housed internally. This advanced design eliminates the need for external features including the motor, gearbox, sprockets, chain, chain guard, and pillow block bearings, making it ideal for the harshest of environments. The Van der Graaf Extreme Duty Mining Series incorporates the benefits of a tried and tested drum motor with an increase in power and capacity. This durable design is entirely sealed from the most challenging work environments, providing a completely reliable, less complex, and virtually maintenance-free belt drive solution.

Drum Motors for Mining and Aggregate Applications Requiring High Power Conveyor Drives The rugged design of the Van der Graaf drum motor is ideal for the harsh and abrasive environmental conditions of the mining and aggregate handling industry. The drum motor encloses all moving parts within an oil bath that prevents dust and grit from wearing out key components. The benefit of this design eliminates the maintenance required on conventional exposed conveyor drives. • Engineered for Harsh Abrasive Environments • Lower Energy Costs • No Maintenance • Up to 300 HP

Pinetree Power, a subsidiary of GDF Suez Energy North America, in Fitchburg, MA, upgraded their conveyor drives to Van der Graaf Drum Motors. This upgrade allowed them to free up between 300 and 500 homes worth of electricity, increasing their revenue, while lowering operating and maintenance costs.

A mining customer’s maintenance strategies were producing good availability results, but to achieve consistency, the customer wanted better visibility on potential upcoming causes of downtime. In this tough environment, major component failure events need to be controlled to minimize impact against budget, and an enhanced solution was required to improve margins. Joy Global approached an existing customer about engaging in a trial period where the two would partner through the company’s JoySmart Solutions offering to improve machine reliability and avoid catastrophic failures on major components. The customer agreed to give Joy Global six months to prove the value of the offering at its coal mine in Australia. The JoySmart team proposed implementation of a newly-developed automated monitoring system that trawls through machine data with the ability to detect any changes in component behavior to predict an onset of failure.