4. What are an air feed’s advantages?
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Versatile air feeds offer great flexibility when feeding various shapes because they can feed unusual shapes in unusual positions. Air feeds handle thin and delicate materials well. In addition, metal formers can feed various materials in any direction. An air feed potentially provide a large grip area with clamps.
Because it has a small envelope, an air feed can be mounted on the bolster plate or die to push or pull material through the die. Its low price tag often justifies permanent installation on die sets to minimize job-setup time. Die-mounted feeds facilitate quick changeover, reduced setup time and no required alignment of feed to die.
5. What are an air feed’s disadvantages?
Progression or feed-length changes can be time-consuming, requiring hand tools and trial and error.
In addition, an air feed requires vigilant maintenance because it must have a constant volume of high-quality air. Excess oil, dirt and water in the air will shorten feed life and inhibit function, and fluctuating air volume will cause erratic feeding. Repair requires complete disassembly and installation of new O-rings and seals. Fortunately, maintenance can be completed simply, inhouse, or a feed manufacturer or distributor can perform the overhaul.
Air feeds generally run best with flat material, so keep an eye on excessive coil set, which may hamper feed motion.
1. Another option for metal formers is a servo feed. How does this type of feed work?
Stampers can speed the feed process by employing programmable servo-motor-driven roll feeds, or servo feeds. Roll release is pneumatic, controlled by a solenoid valve which, in turn, is controlled by the press. Although the press controls can completely take over the servo feed, for the highest level of safety, the press should always control the servo feed. Spring or air pressure controls the feed-roll squeeze.
Servo feeds can be equipped with additional features, such as feed-roll release for pilot pins or camber correction, for variable circumstances. A servo feed can pair with another machine, such as a shear, for cut-to-length operations.
2. What should stampers consider when setting up a servo feed?
Compact servo feeds boast state-of-the-art controls with features that allow the use of simpler, less expensive dies that may be fed diagonally, side-to-side or in any pattern.
Strip alignment is important on a servo feed, too. Use a tool—something as simple as a carpenter square will work—to check that the strip is square from die to payoff reel. The feed can be mounted to the die, bolster plate, adjustable bracket or stand, and mounting should be rigid and oriented straight into the die. The feed should not push material uphill nor downhill, and electric power should be correctly grounded and free of noise.
Like an air feed, a servo feed must be kept clean, particularly the feed roll and control cabinet. Also, protect cables running from the servo motor to the control cabinet to keep them out of the path of forklift and foot traffic.
Roll size matters, more in terms of deflection than grip. A 2.75-in.-dia. roll will not have significantly more material grip than a 1.75-in.-dia. roll, but it may be large enough in diameter so that it won’t bow or deflect.
For optimal material control, upper and lower feed rolls should be of the same diameter. Both rolls should be driven for optimal grip and accuracy. A small upper roll coupled with a large lower roll is difficult to synchronize.
3. What are a servo feed’s advantages?
A servo feed’s production rate is about twice that of an air feed. Given some basic information related to strokes/min., feed angle, feed length and pilots, the feed will calculate the best acceleration/deceleration and speed. It can store hundreds of jobs, enabling job setup via entering a new job number. This ability to recall a stored job with all of its parameters significantly reduces changeover time, and, therefore, facilitates short runs or frequent job changes.
4. What are its disadvantages?
A servo feed requires a higher initial capital expenditure than an air feed, generally quickly recovered with the increased productivity. It requires a programmable control box equipped with cables to the servo, power supply, press and possibly other components. The control box stores job memory and calculates feed progression, speed, acceleration and timing synchronization with the press.
The rolls’ cleanliness and material composition can be highly critical, depending on the specific application, because a servo feed is in constant contact with the material, similar to how a steam roller constantly contacts the ground. This means that any debris on the rollers constantly touches the material. In contrast, an air feed’s grippers do not contact all of the material as they grip the edge, progress, then release. For that reason, material passing through the rollers can deform under excessive pressure, like a piece of dough.
The grip area of the rolls is relatively small compared to that of an air feed. Therefore, a servo feed’s small grip area may necessitate increasing roll pressure, which, in turn, could deform the material.
Quick acceleration and speeds on a servo feed may cause material slippage, which could lead to inaccuracy.
Feeding extremely light, delicate or thin materials can pose challenges without proper alignment, guides and additional pressure on the rolls, which could also lead to deformation of the material. In such cases, an air feed, with custom guides and clamp materials, may be a more suitable option.
5. What are a servo feed’s best applications?
A servo feed opens options to expand production approaches, such as special feed-roll coatings. Urethane-coated rolls protect painted, polished or soft material, while a roll provided with a matte or knurled finish offers improved grip. Servo feed rolls also can be relieved or profiled to handle unusual material shapes.
Servo stagger feed models are designed to help select the best pattern for round or non-round parts. This reduces material waste because it preprograms the optimal pattern and allows the use of irregular-width coil. Servo feeds with a gag program allow a pattern of changing feed lengths with outputs for punch control, and gag programs can be customized.
A tandem servo feed, with an entrance and exit servo to grip and synchronize the material, offers another approach to feed thin or flexible material. Electronic gearing between the two feeds maintains light tension on the material.
Be sure to match the feed capacity to the job for the best performance. Consider the preponderance of jobs, stock thickness, stock width and speed in your operation. Review the operating manual—available online from most manufacturers—to ensure the most accurate match of your job specifications to the optimal equipment. MF
See also: Rapid Air Corporation
This part delves into the concept and usage of power presses in metalworking.
A power press is a machine tool designed to shape, shear, and punch metal using a process called cold stamping. These machines are available in diverse types and are particularly essential for mass production of metal parts. Power presses are primarily classified into hydraulic and mechanical, depending on their power source.
Power presses function through mechanical, hydraulic, and servo motor principles. Mechanical presses convert rotational motion to straight-line movement via a clutch, flywheel, and crankshaft. Hydraulic presses generate force by pressurized hydraulic fluid to mold metals. In contrast, servo power presses use a servo motor to operate the press's slider by powering an eccentric gear.
For all press types, the desired form of the workpiece is achieved as the upper and lower die halves mold the metal under applied pressure.
Historically, metal sheet forming relied heavily on manual labor. The introduction of power press machinery transformed this task by offering amplified precision and mechanical power.
The design of a power press is characterized by its force application technique. Mechanical presses use a flywheel to gather force, transmitting it to the ram. Hydraulic presses depend on hydraulic fluid pressure to drive motion, whereas servo motor presses leverage a motor to convert rotational into linear motion.
Choosing a suitable power press involves various considerations. Mechanical presses are the oldest, while servo motor presses embody the latest advancements. Hydraulic presses became popular as alternatives to mechanical ones.
Hydraulic press technology was invented over 200 years ago by a British engineer during the first industrial revolution to replace steam hammers. Nowadays, hydraulic presses can apply immense pressure, mass-producing a wide array of components.
The functioning of a hydraulic press is based on a pump, endplates, and a piston to induce pressure within a fluid for forming metal. The core of this setup is the pump, driving oil into a cylinder under significant pressure.
The cylinder guides a piston that moves vertically to provide force, acting like a pump and generating the necessary pressure for metal shaping.
A reservoir stores hydraulic fluid, filters out impurities, eliminates air and moisture, dissipates heat, and channels fluid from the reservoir to the cylinder through a tube.
The valve manages fluid flow between the pump and cylinder, regulates pressure, and adjusts the speed and force output of the press. The pressure gauge checks the fluid's pressure, ensuring it stays within specified limits.
The hydraulic pump circulates fluid to the reservoir, changing mechanical energy into hydraulic energy to create an output flow against pressure.
The plates secure the workpiece and offer stability for operations like stamping, piercing, and bending.
Hydraulic fluid moves through a network of hoses connecting the pump, cylinder, and reservoir. Made from durable materials like thermoplastics and rubbers, these hoses withstand high pressure and temperature.
The ram moves along the press frame, applying force on the die. It can travel horizontally or vertically depending on the press's design, with certain models having multiple rams to help the process.
The bed is a stable platform that secures the die while the ram applies pressure.
A servo press operates using a servo motor for precise ram positioning, benefiting industries requiring high precision like aerospace or electronics. The motor connects to a linear actuator, such as a ball screw, converting rotary into linear motion.
In servo mechanical presses, traditional motors and clutches are replaced by servo units, simplifying the structure and enhancing control over ram movement, allowing customized contact with the workpiece.
Servo presses are essential in fields requiring high precision and repeatability similar to stamping and forming tasks, with superior accuracy over conventional presses.
Servo motors power the ram, either via direct drive or with a reducer for efficiency. Direct drives are low-torque and suitable for lightweight presses, while reducer-equipped motors accelerate and decelerate swiftly, powering high-tonnage presses effectively.
The actuator turns rotary into linear motion, most often using ball screw systems offering smooth, efficient, and precise control. A ball screw actuator contains a coordinating screw and nut that refines motion accuracy.
The controller generates outputs from sensor inputs to manage servo motors' nuances, surpassing traditional stroke controls in hydraulic or mechanical presses, allowing intricate programming of stroke length, speed, and pressure.
Sensors - Gather data on position and speed for accurate control.
Human Machine Interface (HMI) - Enables management and real-time monitoring of servo press parameters. Sophisticated setups might include SCADA systems to manage multiple HMIs in a facility.
Core elements of a mechanical power press involve the clutch, crankshaft, flywheel, and moving and stationary rams, connected by "pitmans" or connecting rods.
The crankshaft links to a constantly-moving flywheel powered by a motor. The clutch engages the crankshaft to drive the press’s slide for reshaping tasks.
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The ram exerts the reshaping force, characterized by adjustable stroke length and power, critical in processing the workpiece with a punch tool.
The flywheel, a force-accumulating pulley, leads to consistent ram speed, storing energy to allow weaker motors yet deliver peak tonnage where needed.
A mechanical clutch enables engagement or disengagement of the driving shaft from the flywheel. Power presses either employ full-revolution or part-revolution clutches to control press function, per OSHA regulations.
Brakes promptly cease motion after disengagement from the flywheel, essential for power presses, featuring standard and emergency types for secure operation.
The base forms the structure for supporting clamping mechanisms, dies, and work scheduling within an inclined press. The table size dictates the maximum workpiece size a press can handle.
These transform motor power into ram movement, incorporating pistons or eccentric and crankshaft arrangements. Control mechanisms dictate pressing conditions and safety, increasingly advanced with microprocessors today.
A hefty plate clamps the die assembly, securing the workpiece firmly for accurate operations, pivotal in manually or foot-controlled presses ensuring worker safety.
Operating a power press involves components like the ram, bed, flywheel, clutch, and crankshaft. Primarily, the die-equipped ram presses the metal sheet precisely driven by the flywheel's rotary connection to an activated crankshaft, facilitating the shaping and removal of finished components for repetition.
Determining power press size involves tonnage ratings, worktable dimensions, and the height dedication for opening. Tonnage relies on material factors, while worktable size needs to match material dimensions. Calculation facilitates efficiency analysis for operational speed and suitability in serial production.
Selecting a power press involves thoroughly understanding its purpose and methodical operation. The wrong choice can lead to efficiency loss. Here are important factors to contemplate:
Identify suitable stamping techniques to ascertain punch types based on processing needs, verifying each's operational viability.
Evaluate the benefits of automatic feeding for extensive production beyond - units, assessing transfer processing techniques for diverse projects.
Analyze processing conditions, consistency frequency, and material usage for efficacy predictions.
Effective material handling affects the workload in manufacturing, necessitating streamlined processes.
Understand high single-action punch efficiency in buffering demands requiring complex operations without dual-action machinery.
Estimate required processing pressure through pressure stroke curves, synthesizing multi-project pressure needs for capacity accuracy.
Select presses with ample margins for imbalance when dealing with multiple or continuous die operations with potential eccentric loading.
Set buffer capacity appropriately, recommending dual-acting punches for specific uses upwards of one-sixth of machine power.
Consider the required tolerance levels when selecting press types, with servo models offering optimal precision through advanced controls for challenging applications.
Extensively review cataloged punch specifications for informed decision-making regarding capacity capability and accessory adaption.
Pressing requires comprehensive safety considerations, selecting machines equipped with robust preventive measures to mitigate risks.
Addressing legal restrictions pertaining to noise pollution, select machines with inherent vibration and noise suppression to ensure compliance.
Power presses, essential machines in the metal forming and fabrication industry, can be classified in various ways, including by mainframe type, drive mechanism type, or job operation mechanism. Understanding the types of power presses—such as mechanical, hydraulic, and pneumatic presses—as well as their unique features and use-cases, empowers manufacturers to choose the ideal press for their specific production requirements and ensures operational efficiency.
Power presses are generally categorized as either C-Frame or H-Frame types, regardless of their power source (mechanical or hydraulic). The type of frame is crucial as it determines the press's stiffness, strength, and tonnage capacity—making frame selection a key consideration in metal stamping, punching, and blanking operations.
The C-Frame, so named for its distinctive C-shaped architecture, is designed for smaller power presses with capacities up to 250 tons. This open-frame construction provides easier access for tool changing and workpiece handling but, due to the C shape, exhibits greater angular and longitudinal deflection compared to more robust frame types. This characteristic makes the C-Frame less suitable for applications requiring extremely high precision and extremely heavy-duty forming. C-Frame power presses are most commonly used for presses up to 100 tons and are a staple in small to medium-volume metal stamping, riveting, and punching applications.
C-Frame presses are widely employed for mass production in cold-working processes of ductile metals, such as mild steel and aluminum. Their robust spinning flywheels store kinetic energy, delivering controlled power to the ram during the press stroke. Key components include the plate, bed, bolster plate, and ram, working in concert to provide consistent operation. The knockout mechanism, a standard feature, reliably removes the finished workpiece, reducing downtime and improving production flow.
To enhance longevity and ensure consistent high-precision metal forming, proper cushioning is placed beneath the bolster to absorb the impact generated during heavy stamping and cutting operations. The solid steel construction, reinforced with optimized cross ribbing, supports continuous, high-accuracy production. The integrated clutch enables continuous stroking, facilitating efficient high-volume manufacturing. With a crankshaft forged from a special alloy and fitted with gunmetal bushes, C-Frame power presses are built for smooth operation and extended durability. Precise alignment of the table and ram further ensures highly accurate, repeatable results, crucial in sheet metal fabrication and precision tooling.
The H-Frame, also called the straight-side frame, utilizes a box-type, H-shaped design that delivers enhanced rigidity and virtually zero deflection. This robust frame configuration is essential for smooth, accurate, and precise operations over extended production runs in high-tonnage environments. The structure comprises four box-type pillars and is typically operated from the front, with the job size limited by window dimensions. Compared to the C-Frame and hybrid ring frame press, the H-Frame offers superior stability, precision, and tool longevity, making it an ideal choice for demanding industrial applications, albeit with a higher initial investment.
H-Frame power presses are the preferred choice for medium to high-capacity metal forming, fabrication, automotive stamping, and progressive die work. Size ranges for these machines typically span from 100 to 800 tons, offering either two-point or single-point suspension for added customization based on operational needs. For presses above 400 tons, managing the frame becomes more challenging due to its substantial size and weight, which is why H-Frame models are generally recommended for up to 400 tons unless specialized handling solutions are in place.
Ring frames are hybrid solutions, combining benefits from both H-frame and C-type frame designs. In this layout, the C-type Frame Press provides front-end support, while the open architecture yields increased rigidity and resistance to deflection. These features make hybrid frames especially valuable for presses in the 110-ton to 250-ton range, where a balance between structural rigidity and accessibility is key. The enhanced rigidity directly translates to improved tool life and precision during intensive stamping, coining, and shallow draw processes.
This advanced box-type pillar frame design comprises four main elements: Pillar 1, Pillar 2, Crown, and Base or Bed. High-strength hydraulic tie rods interconnect these parts, effectively absorbing all longitudinal and torsional forces generated during each press stroke. This leads to a highly rigid, safe, and precise frame structure with zero deflection, even under heavy-duty metal forming, drawing, or forging loads. These frames are commonly used in large-scale sheet metal forming, forming with progressive dies, and automated stamping lines, ensuring superior part quality and minimized machine wear.
All power presses rely principally on slider crank mechanisms to convert rotary motion into the linear movement of the ram. Recognizing the distinctions between drive types enables better equipment selection for applications such as blanking, deep drawing, coining, and embossing. There are three primary crank types: eccentric gear, crankshaft, and eccentric shaft. Alternatively, various link drive mechanisms—including knuckle joint and 6-link mechanisms—can be employed instead of the simple crank design. These specialized mechanisms optimize the slide's movement by slowing it during the forming process for superior metal flow and finishing, then accelerating it during the return stroke to maximize production efficiency and reduce idle time.
Integrating gear and crankshaft components, this robust system is engineered for larger mechanical power presses, typically with capacities ranging from 250 to 400 tons and is also used for forming stoves (workpieces) with diameters greater than 10 inches (250 mm). Applications include large-scale sheet metal fabrication, stamping, and deep-drawing operations that require intense force and precision.
The classic crankshaft mechanism is designed for smaller power presses—generally up to 250 tons, occasionally reaching 400 tons. Its simple yet durable construction offers excellent reliability, making it a cost-effective solution for metal stamping presses used in small and medium-sized manufacturing runs. However, it is not suitable for large-format applications or for jobs requiring high stove diameters.
This system is tailored for high-speed, low-stroke power presses with tonnages up to 630 tons and effective for strokes ranging from 4 to 4.7 inches (100-120 mm) or less. Its robust structure enables fast, repetitive punching, blanking, and trimming cycles—making it the drive of choice for progressive stamping dies and automated press lines where speed and reliability are paramount.
The fundamental job operations and working principles of power presses play a critical role in metal forming processes. Mastering these job types helps users select the most appropriate machinery for operations like:
Blanking presses are specialized machines designed for high-speed notching and punching applications. Available in both 4-column and C-frame designs, these presses deliver precise, rapid processing for custom and high-volume production lines. Capacities range up to 100 tons, and modern blanking presses incorporate advanced electronics, PLC controls, and hydraulic systems to achieve unmatched reliability and process control for sheet metal cutting. Companies rely on robust blanking presses to produce high-quality blanks, washers, and metal spacers in automotive, appliance, and electrical industries.
The high-speed stamping press is engineered for rapid, cost-effective production of metal components requiring excellent cutting accuracy and finishing. These machines support manufacturing environments that demand high production rates, short cycle times, and low per-piece costs. With capacities from 630 kN to 1,250 kN and design options in both H-frame and C-frame styles (ranging from 35 to 500 tons), high-speed stamping power presses are essential in precision stamping, progressive die stamping, and high-volume part fabrication such as automotive connectors, electronic components, and motor laminations.
A stamping power press is a versatile metalworking machine widely used to cut, punch, bend, or shape metal sheets with high repeatability and precision. Functioning similarly to a traditional hammer and anvil, it uses male and female dies engineered for the production of automotive parts, electronic enclosures, appliance panels, and structural components. Modern stamping presses can be mechanical or hydraulic in operation and may include advanced automation features for improved productivity and consistent quality.
When considering power presses for your facility, evaluate not only frame and drive types but also job-specific features and automation options (such as feeders, die changers, and safety devices). These factors improve throughput, minimize material waste, and ensure safe operations. Leading manufacturers offer tailored solutions for every application, from prototyping to fully automated stamping lines—enabling businesses of all sizes to achieve optimal efficiency, product quality, and ROI with the appropriate power press technology.
This chapter will cover the applications, benefits, and safety measures of power presses.
Power presses are utilized for a range of tasks, including curling, bending, piercing, and deep drawing. Automation has significantly accelerated power pressing, addressing the industry's demand for faster production, and resulting in cost and time savings. Ongoing research and development aim to enhance these heavy machines' efficiency, increase production rates, and reduce raw material wastage. Power presses are user-friendly and feature advanced safety guards to protect operators, along with technical upgrades that improve press speed and material width handling.
The major applications of power presses are explained in detail below.
Fastening of two or more pieces together. Examples include shafts, bearings, electrical switches, rear axle assembly, water pumps, munitions assembly, fuel injection sensors, windshield wiper blades, gear assemblies, and medical instrument assembly.
Deep drawing is a metal forming process that involves both compressive and tensile forces using a compression power press. A part is classified as deep-drawn if its height is typically about twice its diameter. Common examples of deep-drawn components include oil cans, fire extinguishers, fans, aerospace ductwork, and housings.
Coining is a squeezing process typically performed cold within a closed die, where material is pressed to conform to the die's profile and shape. Due to the high demands of cold working, customized power presses are often used for this application. Coining is commonly employed for high-voltage power lugs and resizing powdered metal components.
A custom power press can reshape a material part without intentionally thinning the material. This process is used for a variety of applications, including electrical housings, journal bearings for trains, medical batteries and device cases, appliances like dishwashers and refrigerators (including their formed and stamped panels), exhaust flattening for mounting, HVAC components, windshield wiper blades, and jewelry.
An operation using a custom power press that imprints designs onto sheet metal with female and male dies, ideally without altering the material thickness, is known as embossing. Examples of this process include creating structural stiffening and applying lettering to sheet metal components.
Punching or cutting openings, such as holes, in metal sheets, plates, or other components using a C-frame power press is a common process. Examples include high-power electrical connectors and automotive exhaust systems.
Secondary shearing or cutting is performed on parts that have already been drawn, formed, or forged. The goal is to trim excess metal from the edges and achieve the desired shape and size. Examples of this process include dishwasher baskets, automotive carpets and dashboards, die-cast trimming, plastic components, and truck body panels.
Joining pieces using an interference fit.
The versatility of power presses offers several advantages:
Like all machinery, power presses also have their drawbacks, which are discussed below.
As power press machines are classified as heavy machinery, it is crucial to adhere to specific guidelines when operating them in a workshop or factory.
Regular maintenance and inspection of power presses are essential for safe operation and extending their lifespan. Therefore, it is important to conduct thorough maintenance and inspections before use.
Workers operating power presses without proper safeguards risk severe injuries, including amputations, crushed bones, and even fatalities. Essential point-of-operation safeguards for power presses include:
Power press machines are highly advantageous and expedient workshop machines wielded for bending, cutting, pressing, and forming metal sheets into different sizes, shapes, and dimensions along with multitasking tools. Power press machines are majorly applied in manufacturing industries for preparing the casing for appliances. Due to their multi-functional features, they are utilized in all factories and industrial workplaces. There are different power press types available in the market, C-frame type and H-frame type, for metal sheet machining work used in the manufacturing industry. A combination of both types is also available.
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