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This article will provide detailed information on finishing machines.
The article will investigate the topics such as:
Finishing machines are machines used for metal finishing, which is the last stage of the metal fabrication process; the stage encompasses the use of machines in finishing the metal surface. This process gives metals a smooth and well-shaped look or result. Tumbling media, plating, and loose abrasives are some of the materials that give aid in achieving the process.
Metal finishing may also encompass the execution of a process for cleaning, polishing, and improving a surface. The process also includes electroplating. The metal finishing industry encompasses a wide range of procedures or processes, each of which offers its own user benefits. It also includes the process of cleaning, revamping, or polishing a surface.
There are several machines that are used in metal finishing, and they vary in capabilities and efficiency. The effectiveness of finishing machines differs depending on size and capacity. This article will delve deeper into the essential finishing machines and their diverse and unique qualities.
Surface finishing comes with several advantages, which are::
There are various approaches used to accomplish metal finishing. These are detailed below.
Metal polishing smoothes surfaces by making use of an abrasive material. This frees metal objects' surfaces of defects and makes them shiny and reflective with an enhanced appearance. In some cases, metal polishing is used in conjunction with buffing, which is not as harsh on the metal surface. As a method, metal polishing has cosmetic value. It also removes oxidation beneath the metal surface, thereby preventing metal corrosion and giving it prolonged life.
The metal finishing process can be accomplished using a variety of abrasives where the material to be polished determines the abrasive to be used. When polishing unfinished material, different stages have to be followed. Firstly, imperfections should be removed from the material using a rougher abrasive. In subsequent stages, finer abrasives are used, which enhance the finish of the material.
A mirror-like finish can be achieved by incorporating buffing and polishing compounds into the polishing wheels. Generally, polishing is applied as is, although lubricants such as kerosene or wax can be used in some cases. Die grinders, stationary polishers, or specialized equipment can be used to give a brighter shine during buffing.
A very fine grit that is copper plated can be used for softer metals such as brass to smoothen the surfaces. The metals are buffed using an airflow mop. Tools such as hammers, wrenches, screwdrivers, and chisels use different polishing approaches due to their uniqueness. The tools firstly undergo roughing through the use of a grinding wheel. Dry polishing materials are then used to finish the materials. Grease can be applied in instances where extra polishing is needed.
The polishing improves the quality of the surface and reduces friction and wear.
Different abrasives are used for different metal strengths in the polishing process.
Metals with low tensile strength, such as copper, brass, and aluminum, use gray silicon carbide abrasives. This abrasive type can also be used on cemented and gray iron carbide.
Metals with high tensile strength, such as carbon and alloy steel, non-ferrous and iron alloys, and abrasives such as white and gray aluminum oxide are used. Green chromium oxide abrasives are used on ferrous metals like steel.
Leather and canvas can be used for polishing. The materials can also include felt, plastic, wool, rubber, etc. Mops or buffing wheels use wool cloth or cotton.
Polishing is necessary in manufacturing processes for products such as kitchenware, cookware, automobile parts, and architectural metal before being released into the market. Metals can sometimes be polished to restore or repair the parts.
Workplace safety can also be enhanced by buffing and polishing. As an example, buffing can aid in corrosion prevention in specialty plumbing. In pharmaceutical and dairy pipes, mold and bacteria can be destroyed, and corrosion is prevented, thereby enhancing product safety.
Extremely flat surfaces can be generated from mass finishing. Metal surfaces with high contact surface ratio like bearings can be generated by smoothing, reducing noise generation, and abrasion. The surface peaks can be reduced to Rpk < 0.1 μ while retaining the valleys, which can be oil pockets. The smoothing process gives a surface that reduces wear and enhances tool life.
Ra values can range up to 0.01 µ and can be achieved uniformly from the smoothing process. This is mostly applied in:
The use of deburring and surface finishing machines is effective or efficient in pile or mass finishing of plastic, rubber parts, ceramic, and metal parts. The use of such machinery in product finishing is of paramount importance in yielding consistent results.
To get quality surfacing, the right kind of process media should be used in conjunction with the individual machine. A water or compound mixture is normally used for wet finishing. This ensures that particles of debris are absorbed and rinsed away, maintaining high efficiency throughout the whole processing cycle and keeping any clogging on media.
In surface finishing, choosing the right combination of process and medium is of paramount importance. Dry finishing is based on dry operations. A sufficiently powerful extraction unit should be used to avoid any problems or casualties when dealing with dry abrasive granulates. This kind of finishing is mostly used for polishing by sticking a polishing paste or powder on the polishing medium. The medium and workpiece experience friction due to movement caused by the finishing process. This results in material stock removal and a well-polished surface.
Both finishing and polishing make use of abrasives. However, finishing removes scratches or surface defects that will have been created from the use of cutting or grinding tools. Polishing provides a gloss or luster on the material surface.
On the other hand, polishing uses abrasive belts, while buffing uses cloth wheels that have compounds applied. The polishing process gives a lined or brushed finish, while buffing gives a bright luster finish and removes lines. Buffing generally needs surface refinement polishing to precede the buffing.
The surfaces can be leveled through polishing using abrasive discs or belts to remove scale, pits, and scratches. The polishing lines can then be removed by the buffing. The finest abrasive should be used when polishing to remove levels, welds, and surface imperfections. Thereafter, the polishing removes the scratch lines.
During buffing, a rotating cloth wheel with fine abrasive compounds is used to produce a luster finish that is bright. The buff wheels also have a greaseless compound-based matrix termed compound. The buff wheel is the compound carrier, and the compound essentially does the surface finishing.
Metal finishing is the critical stage of metal production. The metal finishing process is as follows: grinding, buffing, sandblasting, metal plating, chemical finishing, electroplating, electroless plating, and so forth.
The process exerts friction on the workpiece, extracting imperfections and giving a textured grain that leaves a smoothened exterior finish. The process leaves a non-reflective surface and is done using an abrasive belt or fine bristle brushes. Brushed finishes can be achieved by the use of brush-back sander heads, wire wheel brushes that are stainless steel, nylon discs, and many other abrasive cloth types.
This process makes use of abrasive compounds in order to produce a radiant finish on the metal surface. The process is achieved through the application of the abrasive compound onto a buffing wheel, where the finishing is done by the wheel. A smooth, lined surface is achieved through this fine polishing course process. However, the cut buffing process requires much effort, time, and pressure, making it difficult to operate. Finish buffing then extracts fine lines to give a more radiant surface. Finishing buffing is a much quicker and easier process that demands less pressure. The process smoothens surfaces and rounds out edges. The process is not as efficient in applications that need fragile, intricate, or recessed features due to the cloth wheel’s limited range.
Centrifugal disc finishing, also known as roll flow finishing, is the newest of the finishing processes. It was introduced in Great Britain in 1969 and in Germany in 1998. A centrifugal disc finishing machine consists of an open top bowl with stationary side walls and a rotary disc at the bottom.
The need for shining dull metals, smoothing rough metal surfaces, and softening sharp edges has been a necessity in manufacturing for many years. The basic method for solving the finishing process includes an abrasive finishing media and water.
The first mechanical modern methods for finishing materials were and are rotary tumbling and vibratory systems, which have been successful and productive. The first step toward improving the process was the development of the centrifugal barrel finisher (CBF), which involved placing parts and media in a closed barrel attached to a turret that rapidly rotated the barrel and exerted tremendous force.
As productive as the CBF has been, it involves a great deal of material handling of the centrifugal barrels and longer cycle times than the vibratory method or a rotary tumbling system. Manufacturers wanted the benefits of centrifugal barrel finishing with high process speeds, precision control, and material handling that blended with modern automation.
The quest for a better solution led to the development of the centrifugal disc finisher, which has a round rotating disc at the bottom of a round stationary chamber. The mechanism of a centrifugal disc finisher includes placing parts in the chamber with finishing media, water, and dry or liquid compounds.
When the CDF is activated, the disc rotates at peripheral speeds up to 2000 sfpm or 610 m/min, which causes the mass of parts, media, and compounds to rise upward and outward against the walls of the chamber. As the mass makes contact with the walls of the upper section of the processing chamber, it slows, tumbles upon itself, and falls down and inward to the disc, where the process of rising upward and outward begins again.
The upward and downward movement of the mass resembles a natural vortex. The rapid rotation of the disc adds weight to the parts and media and produces highly aggressive, exceptionally efficient parts finishing energy. The rpms of centrifugal disc finishing can be varied to meet the needs of individual batches.
Centrifugal disc parts finishers finish parts eight to ten times faster than tub or vibratory systems. A two-hour vibratory cycle can be finished by a CDF in 12 to 15 min. A two cu ft centrifugal disc finisher can do the work of a 20 cu ft vibratory system in less than half the time.
These come in distinct types that include dipping or washing of metal during the metal fabrication process. The process involves the use of extremely specific and exclusive chemicals with peculiar features designed for specific metals. Sometimes they are used to create dull surfaces through chemical incision.
Edge rounding is characterized into the following:
The process completes round edges, creates sharp edges, produces unique effects, smooths, and deburrs. Stationery or handheld grinding machines are the two common types of grinding machines. The use of attrition, compression, or friction to smoothen the surface is the principle behind metal grinding. The smoothness of the finished surface is dependent on the grinder used. The different grinding methods are as follows: surface, electrochemical, centerless, cylindrical, and many others. Choosing the perfect methods depends on the product and metal type.
This is the process of depositing a metal coating onto a surface or workpiece by giving it a negative charge when it is settled in metal salt. A thin metal coating is produced by attracting the negatively charged material to the positively charged. The process can be completed by dipping metal into a metallic solution called electroless plating or electroplating.
The process known as thermal spraying involves coating the surface using a molten material at an elevated temperature. The surface is heated rapidly at a high velocity, then suddenly cooled to give a hard, solid coating. This coating protects the metal from wear, corrosion, erosion, wear, and elevated temperatures. The process can result in changing workpiece electrical and appearance properties when applied right.
This process usually abides by environmental regulations and is also a process that is associated with quality produce and efficient processing. It makes use of polyurethane resin merged with leveling agents, pigments, additives, and flow modifiers that are melted and mixed in a powder that seems like baking flour. The powder is applied to the metal’s substrate using an electrostatic spray, and then an oven is used to cure the parts. Powder coating can also be applied to nonmetal surfaces like certain classes of fiberboard and plastic. The process can also be used to get rid of deformities and defects.
This process helps in getting rid of debris, dirt, and particles that can pile up on a surface throughout the process. This saves time and cuts costs as there will be no time needed to clean the surfaces after the processing. The process offers high efficiency and productivity since it is up to 75 percent faster than other methods. The process makes use of abrasive materials like silicon carbide, glass beads, plastic abrasives, aluminum oxide, and corncob grit. The materials produce different finishes, from textured designs to a soft satiny look.
The smoothing process offers a short cycle and low unit cost way of surface finishing. In automotive, it is best suited for polishing and smoothing gear wheels, pistons, camshafts, expansion screws, rocker arms, and valves. In metalwork, smoothing is done for high-speed spindle smoothing, and in forming tools, for forming and pressing surfaces, polishing and smoothing.
The term is mostly used in the metalworking industry to depict the process of removing sharp edges from metalwork pieces or parts after manufacture or treatment. Stream or drag finishing machines are used for large and heavy metal pieces that are not combined during the processing. Choosing the suitable abrasive media is essential since the burrs or sharp edges are to be completely removed, not just bent over. Specialized knowledge and experience are a necessity for anyone or team that will carry out the process.
Finishing machines come in different shapes, sizes, and functions. This part will give a more thorough detail of the finishing machines and their divergent functions.
A common type of finishing machine is the vibratory finishing machine. They have several benefits which are but aren't limited to:
This finishing process is more combative compared to the finishing method above. The centrifugal barrel finishing machine operates using 3 to 4 barrels that are attached to the turret assembly. The fast process is because of the high centrifugal forces that are triggered by the turret’s high-speed rotation.
Variable frequencies are used to operate the machine in line with the rotational speed needed per process, resulting in a more even and uniform surface finish. The industries in which machine use dominates include bearing, compressor, automotive, jewelry, textile, and aerospace.
This finishing process involves the clamping of workpieces in holders that are specially designed, following the dragging of the holders in circular formatting through a process drum with polishing and grinding granules. The accelerated speed movement produces an elevated contact pressure in the midst of the media and workpiece. The pressure then results in the perfect forming of high precision smoothing and edge rounding that seems like it has been done manually.
This type of plating involves the use of chemical reactions simultaneously with the aid of an aqueous solution. One plating method occurs when a surface is concealed by a thin metal sheet, and heat and pressure are applied to merge them. In plating, the following materials are used: composite, gold, chrome, alloy, cadmium, zinc nickel, zinc, rhodium, nickel, and gold. In the jewelry manufacturing industry, plating is done to a gold or silver finish. Metallizing is coating metal onto nonmetallic workpieces or objects.
This type of vibratory finishing machine is used in industries where there is less than 10 minutes of processing time. The elliptical machines are used for extracting light burrs and for small parts finishing like bearing cages and ceramic insulation tiles.
The plating finishing machine operates by inserting a layer of plating on the surface of the material to achieve adhesion, strengthening, friction reduction, decoration, solderability resistance, and a lot more properties. Even though this process has been done for a long time, it is still of paramount importance in modern-day technology. Usually, the material possesses a desired quality that is not on the main material. It may also offer the following: attractive surface, resistance to corrosion, and magnetism.
Modern-day findings have necessitated the plating of workpieces with the aid of liquids.
Barrel finishing machines are sometimes called polishing barrel tumblers. They have 6 or 8-sided rotating drums that can be deburred, rounded, or surface treated. Lubricating agents, abrasives, and tumbler media are used to create friction in the barrel drum and to increase abrasive material effectiveness. There are two basic varieties for polishing tumblers, which are wet and dry tumblers. Wet tumblers have a slow-paced cutting rate that produces a finer finish, and this makes them more efficient in the removal of excess stock. Dry tumblers operate using a vertical essential in handling materials across the entirety of the finishing stages.
The barrel finishing machines sometimes called barrel tumblers have 6 or 8 sided rotating drums that can be deburred, rounded, or surface treated. Lubricating agents, abrasives, and tumbler media are used to create friction in the barrel drum and to increase abrasive material effectiveness. There are two basic varieties for barrel finishing machines which are the wet and dry tumblers. Wet tumblers have a slow paced cutting rate that produces a finer finish, and this makes them more efficient in the removal of excess stock. Dry tumblers operate using a vertical essential in handling materials across the entirety of the finishing stages.
The bowl round machines are urethane-lined horizontal machines with a donut-shaped container that has an open top. The donut-shaped container has a vertical eccentric shaft drive that is well proportioned across the center column. Around the center column, there is a media mass spinning in a rolling forward motion feed. These are the most common types of machines used in the manufacturing industry. The machine helps keep parts comparatively oriented to avoid any damage.
The bowl can be divided into large parts, and the greatest advantage of using the machine is that gates, screens, and ramps can be loaded into the bowl. This will also enable the self-unloading of parts from the finishing machine and media. They are used mostly to finish small parts like screws and rivets, including bigger ones like turbine blades.
This type of finishing machine is well known for its ability to perform both the cleaning and smoothening of the metal all at once. The machine operates by inserting abrasion agents, such as metal pellets or sand particles, into the setup at an accelerated speed. Speed of the abrasion particle, duration of the cleaning stage, and angle of the prepared fire determine the level of finishing.
This is a modified version of the Round Vibratory Finishing Machines. They ensure a thorough and complete separation of parts in a brief time of 8-10 minutes. Process efficiency is better than in round vibratory machines due to the bowl’s spiral shape. The spiral vibratory finishing machines are commonly used in the finishing of parts for the bearing industry, furniture industry, and valve bodies.
Stream finishing machines are called SF technology, and they are a great presentation of modern-day mass finishing machinery. The process involves the workpiece being clamped and lowered in a holder into a spinning container, polishing, and grinding a medium-filled container. The independent rotation of the workpiece and the flowing polishing or grinding medium are both responsible for generating the real finishing motion. This process gives reliable and consistent results in a short finishing time whilst enabling a selective removal of materials.
This type of vibratory finishing machine is used in degreasing, polishing, and deburring mid-sized parts such as rods, marble and granite tiles, turbine blades, shafts, axles, aerospace parts, and a lot more. Their capacity gives maximum channel width and enables parts to be separated easily with removable compartment dividers.
The tub finishers’ structural design is stronger and firmly joined together, giving a U-shaped trough encrusted with a premium polyurethane lining than is fixed on coil-coated springs. The drive has a premium effectiveness motor that controls an offset drive shaft with weights that can be easily adjusted. The increase or reduction of machine combativeness weights is made by adjusting the weights. The system is mostly fueled by a shaft that has an eccentric hook on the tub, a sheave, motor drive, and V-belt are used to rotate or spin the shaft. Eccentric weights may be loaded or unloaded around the shaft to reduce or add vibration.
Unique machinery exists and uses various techniques. Examples of such machinery include:
These are often used in larger applications and can remove scale, rust, or paint from metals at a much faster rate. The abrasive blasting machinery can be a chain-fed conveyor or operated sandblasting system that can process 1000 pounds (454 kg) of steel per hour.
This method uses the belt sanding method together with either a drum style rotating abrasive brush or a cup style rotating brush. The brushes are made from a resilient material and coated with abrasives like garnet to increase strength through surface finishing and material removal properties. The main aim or purpose of the system is also to round sharp edges and deburr the material surface to ensure safe handling of parts for later use.
This finishing process is ideal for metal areas with smaller parts that may be hard to reach like pockets, chambers, and deep holes. The magnetic polishing process entails putting components in a tub or box that will be filled with magnetized particles. Particles are directed to rub the inner parts of the hard-to-reach spots giving a smoothened and excellent polish. The magnetic polishing process gives intricate parts resistance and soft polish that makes them resistant to air or liquids. The process yields excellent results by giving a perfectly finished surface and is at the same time cost-effective. The finishing process does not only yield improved surface quality but also rounds and deburrs to a specialiEd degree.
The type of finishing process entails coating of material’s surface with black oxide in a bid to enhance the look and the abrasion resistance.
This kind of technique offers the removal of small burrs, metal points, and surface finishing. The tumbling process entails inserting components in a box together with abrasive particles and then vibrating the machine to combine everything together. The vibratory process extracts burrs and gives a fleck that can be used directly or coated easily using paint, powder coat, clear lacquers, or any other material that gives a more durable finish that won’t yield to scratching and chipping.
This finishing method is used for cleaning smoothened and curved surfaces through the process of forming irregular, non-linear textures. This method can involve different abrasive media, and a higher grit number plus finer or smaller particles give a more elegant finish. Finer grits result in mirror polish like stainless steel, whilst coarse grits help in getting off materials at a faster rate. The machines can be an automated belt system or a belt sander operated manually that passes down materials to be processed below a rotating belt or more as per need to achieve the desired outcome.
All the finishing machines are chosen according to the needs of the project, and below are some of the left-out lists of finishing machinery.
These have a bowl-lined polyurethane that is positioned on springs and made of vibratory motor and imbalance masses to give gyroscopic motion. This is used for descaling, polishing, smoothening, degreasing, mirror finishing, and edge control for several components. This method is used mostly for deburring and polishing molded, forged, sheet metal, machined, and cast parts.
This type of machine can be used to process a wide range of components like aerospace, consumer products, automotive, and defense. To give a dampening effect, water may be used as it helps lower the cutting rate. This comes in handy for operations like burnishing, where a minimum cut-rate is mandatory. The vibratory finishing machine encloses metal in extreme frequency motion with up to 1800 vibrations per second.
This section will detail the advantages and disadvantages of some of the different finishing machine types.
The advantages of using barrel finishing machines are as follows:
This chapter will discuss considerations when choosing the right finishing process and the right finishing machine.
The finishing process is the last stage in the production of perfect product texture and look; it complements workpiece design and gives protection from rust, tarnishing, and corrosion while adding strength, thickness, durability, and hardness to the finished product.
Cost is the first consideration in the production process; for example, types of costs like the type of coating, expended energy, various consumables, amount of waste, cleanup, and labor costs.
The type of metal to process should also be considered to choose the right finishing process and machine. The types of metal differ, from aluminum to stainless steel; thus, there is a need to understand all the types and find a more profitable result.
There is a need to know the processing time for different processes in order to choose one that meets the time constraints of the project. A careful consideration of time constraints will help meet deadlines whilst ensuring a more efficient processing time. Careful consideration of time can also help maintain stability in the supply chain system whilst avoiding costs and errors that may come from working at the last minute.
The degree to which a metal can be fabricated and manipulated is determined by the durability, strength, and endurance of the metal. Metal strength is dependent on the types, use, and different applications. The three factors in determining metal strength are ultimate, yield, and breakable strength. Yield refers to a metal deformation period, whereas ultimate means the level of stress a material can endure. The metal fabrication process's success is dependent on the choice of the finishing process, and the right decision saves labor, cost, and time.
Various considerations are necessary when deciding on the right deburring and finishing machine. These include:
Choosing the right machine that is consistent with the needs of the finishing process requires one to make sure the machine serves its intended purpose. The dry machines are most suitable for an industry where similar materials are ground consistently.
For industries where there are distinct types of materials involved, wet deburring and finishing machines are the best choice. A consideration of the workpiece’s qualities and specific characteristics as well as the type of abrasive is essential in ensuring the maximum performance of a machine.
There is a need to consider the labor force characteristics that will assist in the process, for example, the number, technical expertise, and so forth. More people involved in the process means the choice of machinery is also open to high-maintenance machines. A more skilled labor force means they can work with automated machinery.
The more time a process or project takes means more money is used and also may cause problems in the supply chain if products don’t meet the expected date. There is a need to choose a machine that goes along with the production allotted time.
The choice of finishing machinery should be within the allocated budgeted amount. That is, one is supposed to factor in the cost of operating the machine and whether one can afford the technical expertise to operate and maintain the choice of machine. Without careful consideration, such a key factor may affect the quality and quantity of products from the process.
Making a perfect choice for a deburring or finishing machine is not for the fainthearted, thus the need to get help from professionals. In this case, one may find it helpful to consult metal fabrication experts. There are a few factors to be considered during the selection of the expert to consult, which are not limited to: relevant industry experience, whether they have the right manufacturing partners, and references from previous customers so you can know the kind of services they or offer.
It has been proven that metal finishing is as important in the production process as any other stage. To produce resilient, strong, and well-presented products, it is essential to pay much attention to what finishing suits a specific item. Workpiece characteristics have a lot to play on the choice of finishing process and machinery selected.
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