It is important for a press brake to be accurate. Even small errors can lead to big issues or wasted materials.
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Several things can change how accurate a press brake is. These include the quality of the machine itself, the tools it uses, the type of metal being bent, how good the person operating it is, and how well the machine is taken care of. Even though technology has improved and allows for very exact bends, it is still important to check these machines regularly.
We need to follow certain rules, like GB/T-, to make sure the press brake works right. This means not just looking at it, but also checking how well it performs.
In this article, we will explain what makes a press brake bend accurately and give tips on how to keep it precise.
Press brake accuracy means how close the bent angle and sizes are to what they should be.
This accuracy includes not just the final angle of the bend, but also how consistently the machine can make the same bend repeatedly, how exactly the bend is placed, and how even the curve and shape of the bend are.
Better accuracy means less wasted material and makes sure parts fit together correctly when being put together. This is especially important for making things efficiently.
Two key things that affect how accurate a press brake is:
When a press brake is properly taken care of, it can usually bend within about half a degree (±0.5°) and position things within about 0.1 to 0.2 millimeters.
This level of accuracy makes sure that press brakes can work well for various kinds of metal bending jobs.
Outside things like differences in how thick the metal is, how well the machine is set up, and how consistently the operator works are especially important for keeping this level of accuracy.
When everything is exactly right, computer-controlled (CNC) press brakes can position things extremely accurately, often within an exceedingly small fraction of an inch (0.001″–0.004″).
Other information that can help you achieve better accuracy:
The best accuracy that can be achieved for press brake operations can be as small as ±0.1–0.2 degrees. Using advanced computer-controlled (CNC) technology, excellent quality tools, and metal that does not change many helps in reaching this level of accuracy.
Top-of-the-line press brakes that have features like automatic adjustments, instant feedback, and laser measurements can reduce mistakes, keeping the bending angle accurate to less than ±0.1 degrees when everything is perfect.
Here are two keyways to get the best accuracy:
When talking about press brakes, accuracy means how close the bends are to the correct angle and size. Precision means how well the machine can make the same bend repeatedly.
For example, a press brake might be exactly accurate, with the bending angle being remarkably close to the target (±0.2°). But if each part that is made has a slightly different angle (by ±0.5°), then the machine’s precision is not as good.
Precision vs. Accuracy in Production:
Bending metal accurately using press brakes depends on five things that can really change how good the final product is:
The type of metal being bent is especially important in deciding how precise you need to be and how you will achieve it:
How thick the metal also plays an especially key role in how accurate the press brake can be. Even slight differences in thickness, like 0.1 mm, can really change how much the metal springs back and the final bend.
Thicker metals need more force, which can cause the press brake machine to bend slightly unless it has features to prevent this, like automatic adjustments or sensors that give real-time feedback. It is important to measure the thickness of the metal in various places before bending it to expect and fix any mistakes.
Using “test pieces” or samples from each batch of metal allows the people operating the machine to adjust the settings for the best performance based on how the metal behaves. This makes sure that everything is consistent across all the parts being made.
How hard and strong the metal also really affects how accurately it can be bent.
Harder metals do not bend easily, so you need to use more force to bend them. This can put a strain on the press brake if it is not strong enough or hasn’t been taken care of properly.
If the hardness of the metal is different across a batch, it can cause the bending angles to be inconsistent. To deal with this, companies often use tests like Rockwell or Brinell to measure the hardness and then adjust the machine to get the right bends.
Also, if the metal has different structures inside, you might need to make special adjustments or even heat it up before bending to make it less likely to break and to make the bending more consistent.
Springbuck is when the metal tries to go back to its original shape after you bend it. How much it springs back depends on the type of metal and things like how strong it is, how thick it is, and how sharp the bend is.
It’s especially important to control spring back to bend accurately. One way to do this is by bending the metal a little bit too far so that when it springs back, it ends up at the right angle.
Some of the best press brakes have special sensors that can measure how much the metal is springing back while it’s being bent. The machine can then automatically adjust to make sure the final angle is correct, so you don’t have to make changes later.
If you bend the metal in the same direction as its grain (like the lines you might see in wood), it’s more likely to crack or have uneven angles. This is especially true for extraordinarily strong metals where the grain can make the spring back even more unpredictable.
If you need to make sharp bends or small curves, it’s usually better to bend the metal across the grain. This helps prevent problems like the metal breaking.
To keep things consistent and make sure the bends are good, many metalworking shops mark the direction the metal was rolled in on each sheet.
This helps the people operating the machine put the metal sheet in the right way so that important bends are made across the grain whenever possible.
If there are small edges that must be bent in the same direction as the grain, the operators need to be extra careful to avoid the metal splitting or the angle changing unexpectedly.
Also, when planning how to cut the parts from the metal sheet, it’s a clever idea to arrange them so that the most important bends will be made across the grain.
If the metal has a coating on it, like paint, primer, or something else, it makes bending a bit more complicated. These coatings can change how slippery the metal is against the tools, which affects how the metal moves when it’s being bent.
If the coating is too thick or there’s dirt on the metal, it can cause extra pressure in certain spots and leave marks. This can change the final angle of the bend.
It’s especially important to get the metal surface ready properly. The people operating the machine often need to clean the metal well and might even remove the coating where the bend will happen to make it less slippery and to stop any damage to the tools or the coating.
Sometimes, the metal has stresses left over from when it was made. These stresses can cause the metal to bend out of shape or spring back in unexpected ways, which can make the bending less accurate.
For metals that are likely to have these problems, especially thick pieces, the companies that make the metal might use methods like annealing (heating and cooling the metal slowly) to get rid of the stresses before it’s bent in a press brake.
When working with the metal, the people operating the machine might notice that big or thick pieces, especially those cut close to where metal was welded together, act differently because of these leftover stresses.
To deal with this, they might try bending a test piece first or bending the metal more than once to spread out the stress more evenly. However, this can take more time.
If the sheet metal is slightly curved or wavy, it can get really bent out of shape when force is applied. This is especially true for big parts, where even small bumps can cause big mistakes along the bend.
To avoid these problems, it’s important to check if the metal sheet is flat and fix any curves or waves before putting it into the press brake.
They might use machines to flatten the metal or check each piece by hand to make sure it lies flat against the tools. This is especially important for getting consistent bends.
If the metal sheet isn’t sitting flat on the bottom part of the tool, even slight differences in how it’s lined up can cause big mistakes in the angle or size of the bend, especially for long bends.
Even small flaws, like tiny broken pieces or rounded edges on the die, can cause the bending angle to be noticeably wrong.
It’s especially important to use excellent quality dies that have been ground to be very precise. This helps keep the V-shape opening or the curve of the die the same, which is needed to prevent unexpected changes during bending.
The tools will also last longer if you choose dies made from stronger steel or ones that have a special coating, like nitriding. These are less likely to get worn out.
Regularly checking the dies to make sure they are set up correctly, including measuring the openings with special tools, makes sure they match the planned design.
You also need to pay attention to the surfaces of the dies. Any damage or uneven spots can cause the bends to be different across the piece of metal.
For jobs that need very precise bends, it’s a clever idea to keep a set of “master” dies in perfect condition and use older dies for less important jobs. This helps manage how quickly the tools wear out while still getting the work done.
Even if the dies are just a little bit out of line, by even a fraction of a millimeter, it can make the bend uneven along the length of the press brake.
Tools like lasers or dial indicators are often used to check if the top part of the tool (punch) and the bottom part (die) are perfectly parallel.
For bigger or longer dies, it’s especially important to measure the space between them at different points along their length to make sure they are parallel.
This helps in setting up the crowning system, which is a way to make up for the fact that the press brake might bend slightly in the middle when it’s working.
It’s also important to make sure that any quick-change tool systems are locked in tightly. If they’re not fully in place, the punch or die could tilt, causing uneven bends.
For press brakes that are operated by hand, the people using them might need to check the alignment more often, especially after they change the setup or when they use various parts of the die for different jobs.
If the edges of the punches and dies get dull or chipped, it can cause the bending angle to be inconsistent, which is a big problem when you’re bending a lot of parts.
It’s especially important to check the edges of the tools often because a worn punch tip can bend the metal too little or leave rough edges on the surface, which makes the final product not as good.
Regularly sharpening or replacing these tools makes sure that their shape stays accurate, which is the most important thing for keeping the bending accurate.
Even small dents in the opening of the die can cause small but noticeable differences in the angle or size of the bend. Measuring how curved the tip of the punch is after making a lot of parts helps decide if it needs to be sharpened.
If the opening in the V-die is too big, it usually takes less force to bend, but the metal might spring back more. On the other hand, if the opening is too small for how thick the metal is, you might need to use too much force, which could cause the metal to crack or the tools to wear out quickly.
For bending accurately, it’s recommended to use a die opening that is about eight times as wide as the metal is thick, but you might need to change this depending on the type of metal or what the design needs.
If you change the size of the V-die opening without also changing how the machine is set up to bend, it can cause the bending angle to change in ways you didn’t expect.
Using dies that have multiple V-openings that can be adjusted can be an effective way to work with different thicknesses of metal while still getting consistent bends.
Some tools are made to last longer when bending rough materials like stainless steel. If you use the wrong tool for the material, it can cause the metal to stick to the tool, get scratched, or even break while bending.
Making sure that the tool is hard enough for the metal and that the tool is the right size for how thick the metal is especially important for making the tools last longer and getting consistent bends.
Tools that have hard coatings, like punches with nitride or carbide tips, create less friction and wear out slower, especially when bending strong metals.
On the other hand, softer metals like aluminum might bend the tools out of shape if the tools aren’t made of good enough steel or if you use too much force when bending.
It’s especially important to use high-quality steel for the tools that has been treated with heat or coatings. This is because they stay sharp longer and spread out the force of bending better. Using cheap materials can cause the tools to bend out of shape quickly, and you’ll lose accuracy in the sizes of the parts. This is a big problem when making a lot of parts because even small errors can lead to a lot of wasted material.
Companies often do tests on the metal used for the tools, like hardness tests, to make sure it meets the necessary standards.
If the steel used for the tools is not excellent quality, it might crack or break under a lot of pressure. This can not only damage the part being made but also be dangerous for the people operating the machine.
The depth and shape of the V or U opening in the bottom tool (die) need to be exactly right for how thick the metal is and what kind of bend you need to make. A deeper opening can help stop thicker metal from cracking, while a narrower opening is needed to get accurate angles on thinner metal.
There are also special die shapes, like gooseneck or offset dies, which are made for making complicated bends. These need to be checked regularly for wear or if they’ve gotten bent out of shape. If the opening in the die is not the same along its length because of uneven wear, it can cause the bending angle to change.
If one part of the die gets worn out more than others, often because you’re always bending in the same spot, you can make the wear more even by turning the die around or flipping it over from time to time. Using special ways to analyze the wear and checking the dies regularly can help find the worn-out spots early so you can fix them before they cause problems.
If you often make small parts at the ends of the machine, the die might get worn out more quickly in those areas. Using several shorter pieces of die instead of one long one can help spread out the stress and wear more evenly, which helps keep the bending consistent.
If the clamps holding the punches or dies are loose, the tools can move while the metal is being bent. This can really mess up how accurate the bend is.
Using clamps that can be quickly released and are very precise, or strong hydraulic clamps, can help keep the tools lined up correctly during the entire bending process.
It’s important to regularly check how tight the clamps are and if they are lined up correctly. You also need to make sure the surfaces of the tools are clean and don’t have any oil or dirt on them.
Before starting to make a lot of parts, doing a “wiggle test” can make sure the die or punch is held in place securely. Also, using automatic clamping systems that have sensors to check if the die is fully seated can reduce setup mistakes and make the entire process more accurate.
How curved the tip of the punch is especially important because it decides how curved the bend will be and how much the metal might spring back.
Using punches with a bigger curve on the tip is often good for bending thick or extraordinarily strong metals. This helps spread out the stress over a larger area, making it less likely for the metal to weaken or break.
On the other hand, using a punch with a smaller curve can put more stress on the metal, which might cause more brittle metals to crack. Making sure the curve on the tip of the punch is the same for every batch of parts is important for getting consistent and reliable bends.
Many workshops keep a collection of punches with different curves on their tips so they can quickly change them to meet different bending needs.
Crowning systems are an important part of press brakes. They make the bends more accurate by making up for the fact that the machine might bend slightly when it’s working. These systems can be mechanical, like using wedges to adjust, or hydraulic, which can automatically adjust to the force being used.
It’s especially important to set up the crowning system correctly. This makes sure the pressure is spread evenly along the bend, which is crucial for getting the same bending angle, especially for long bends that are longer than two meters.
Crowning systems on computer-controlled (CNC) machines adjust automatically when force is applied. But on manual systems, the person operating the machine needs to try bending some pieces and then adjust get the accuracy they want.
Scratches, rust, or dirt on the surfaces of the die can get onto the metal. This can change how slippery the metal is and leave unwanted marks on the part being made.
To make sure everything runs smoothly and there are as few marks as possible, it’s important to keep the die surfaces polished or coated. Regularly cleaning them and taking steps to prevent rust is especially important, especially in damp places where rust can quickly damage the dies.
Regularly taking care of the dies, like wiping them down with the right cleaners or lubricants, is especially important to prevent scratches that could cause small pieces of metal to get stuck and affect the metal sheet.
Also, using protective films or inserts on the dies can really help reduce scratches on the surface of the metal. This is especially important when working with metals that have a shiny finish, like polished aluminum or stainless steel.
A sturdy frame makes sure that the force used for bending doesn’t cause the machine to bend out of shape. This is especially important for preventing the bending angle from being wrong. Even a small tilt in the frame, like 0.1 degrees, can cause big differences in how evenly the force is applied, which can make the bending accuracy off by as much as ±0.5 degrees.
To prevent these problems, press brakes often have strong steel frames and solid structures, including well-designed beams that help keep the machine from bending too much when force is applied.
How flat the table of the press brake is along its length directly affects how straight the part being made will be. If the table is off by just 0.06 mm, it can cause a 0.17-degree error in a 90-degree bend.
How well the hydraulic system works is especially important for making sure the ram moves consistently, which leads to consistent bends. The pressure of the fluid needs to stay steady to avoid air bubbles or leaks, which can cause the force to be unevenly applied.
Regularly taking care of the system, like changing the hydraulic oil and checking the seals, pumps, and cylinders, is especially important for keeping the system accurate.
Problems like having too little oil or oil that is dirty can make the ram move unevenly, which then affects how consistent the angles are on different bends. Worn-out valves and pumps can make the ram respond slower or inconsistently, which is why it’s important to calibrate the system every year.
Listening for strange noises or feeling unusual vibrations in the hydraulic system is an effective way to find and fix problems before they make the bending accuracy much worse.
If the back gauge is not lined up correctly or if it’s loose, it can move the place where the bend happens and change the angle you wanted.
Modern back gauges that are controlled by computers (CNC) and have linear guides can position the metal very accurately, within a tiny fraction of an inch. This makes sure the metal is lined up correctly before bending.
Regularly setting up the back gauge correctly, which involves checking its alignment in various positions (all the way back, in the middle, all the way forward), is especially important for it to work consistently. Also, the parts that hold the metal (gauge fingers) need to be in good condition. If they are worn out or damaged, they can tilt the metal sheet, causing mistakes in where the bend happens.
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When the press brake is under a lot of pressure, the top beam (ram) might bend a little bit. This can cause the bending angle to be different in the middle compared to the edges of the metal piece.
To fix this, machines use things like crowning systems, strong frames, and adjustments to the motors to reduce how much the ram bends. This helps keep the force of the bend the same across the whole piece of metal.
If you’re bending mostly on one side of the machine (not in the center), the ram might bend even more. It’s usually best not to bend off-center unless the press brake is made to manage that.
Some of the newer press brakes can watch how much the ram is bending in real-time. They can then automatically adjust the hydraulic system or motors to make up for any bending they detect.
As the machine gets older, the moving parts and guide rails can wear down. This means you need to set up the press brake again (calibrate it) to make sure it stays accurate. Checking the calibration often, like once a month or every three months, is especially important for keeping the machine working within its intended accuracy. If you don’t maintain it regularly, the bending angle can slowly change, and the bends might not be consistent, leading to more wasted parts and higher costs.
A press brake that is set up correctly makes sure parts are made accurately, which means less waste and fewer parts that need to be fixed. Important steps for calibration include checking if the ram is at a right angle to the frame and if the back gauge is lined up correctly.
Following the rules set by the country or the industry for how much error is allowed in the machine is especially important for keeping the machine accurate in its shape and how it works.
The best press brakes have very precise measuring tools that can tell exactly where the top beam (ram) is. They can usually repeat the same position within ±0.01 mm or even better.
This very precise control is especially important for making sure the bending angle is the same every time, no matter what you’re bending.
However, if dust or dirt gets on these measuring tools, it can cause wrong readings and make the bending inaccurate. It’s important to clean these parts regularly to keep them working well. Also, bending a test piece at the beginning of each workday can help make sure the ram’s position matches what the computer program says.
To make things even more accurate, some systems have automatic tools that measure the actual bending angle and compare it to what the machine’s sensors say. This helps find any problems with the accuracy of the sensors.
Modern press brakes have automatic systems that make up for the machine bending. These systems adjust how far the ram goes down or change the angle of the tools while the bending is happening, based on what sensors are telling them or on settings that were put in before.
These systems are helpful when you’re making parts that have different lengths or thicknesses in the same job. They change the machine’s settings to make up for any bending that might happen.
These systems often remember the best settings for jobs you do often, which makes it faster to set up the machine the next time. But if the sensors that tell the system what to do get out of line or get damaged, the system might cause mistakes instead of preventing them.
It’s especially important for the hydraulic pressure to stay steady so the bending happens at the right speed and with the right amount of force. Keeping the fluid at the right temperature and regularly cleaning it and taking care of the pump can help prevent the pressure from changing too much. Even slight changes in pressure can cause the bending angle to be off by ±0.2–0.3 degrees, which can make the bend less precise.
When the temperature in the workshop changes with the seasons, it can change how thick the hydraulic fluid is. This can slightly affect how much force is used for bending.
Watching the pressure gauges while the machine is working lets you see if there are any sudden drops or increases in pressure, which could cause the bending angles to be inconsistent.
Also, keeping the hydraulic fluid at the right level in the tank is important to prevent the pressure from becoming unstable, which could affect many bends.
It is especially important that the moving parts, like the cylinders on the left and right in hydraulic machines or the servo motors in electric machines, stay parallel to each other. This makes sure the top beam (ram) stays level during the entire bend.
If these parts are even a little bit out of parallel, one side of the metal piece might bend more than the other, causing the angles to be wrong.
Regularly checking if these parts are parallel using digital displays or mechanical measuring tools is especially important for setting up the machine correctly and keeping the bending accurate.
Some press brakes have special sensors that can watch the position of each cylinder separately. This lets the machine’s computer system fix any unevenness it finds.
Over time, the parts that connect the moving parts might wear out and need to be taken care of to keep them working together correctly. This is especially important when bending long pieces of metal because even slight differences can become much bigger problems.
It is especially important to set the distance the ram travels (stroke length) correctly to avoid bending the metal too much or not enough. Computer-controlled (CNC) press brakes can save and manage the right stroke lengths for diverse types of metal and bending angles, which helps reduce mistakes.
When setting up the machine, the stroke length is checked by measuring how far the tip of the punch is from the surface of the die to make sure it is accurate.
If the stroke length is not set right, the metal might get stuck at the bottom of the die, which can change the bending angles and even damage the tools.
Some press brakes have a “test mode” or let you move the ram slowly so you can adjust the stroke length very precisely before you start making a lot of parts. This makes sure the settings are correct for the metal and the die you are using.
Bigger machines can manage wider sheets of metal, but they might bend more if they are not built strongly. It is especially important to use a machine that is the right size for the part and the thickness of the metal to avoid putting too much stress on it. Overloading the machine can permanently bend its frame and make the bending less accurate.
For machines with exceptionally long tables, you need to check often to make sure they are still even and not bending up in the middle. Also, trying to bend metal at the very ends of a large press might give you uneven angles if the machine is not made to handle bending off to the side.
If the machine is set to work amazingly fast, it might make mistakes because of the force of its movement, especially if it does not have effective ways to slow down smoothly or control its motion in real-time. To fix this, the speed needs to increase and decrease smoothly, and the motors or hydraulic system need to be well-adjusted to keep everything stable during bending.
Newer technology has mostly gotten rid of the problem where you had to choose between speed and accuracy. Modern machines can work amazingly fast without losing the ability to make very precise bends.
However, it is especially important for the people operating the machine to make sure that the fast movements do not cause the metal to slide around or the back gauge to shake, which could make the bends less accurate.
Press brakes that are made to bend a lot of parts quickly often have special motor controls that are particularly good at making sure the ram does not go too far at the start and end of each bending motion. This makes the entire process more efficient and accurate.
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Operators who are good at their job know a lot about how different metals act, how the machines work, and the slight differences between diverse ways of bending, like air bending, bottoming, and coining.
Because they are skilled, they can quickly see and fix any mistakes that happen during bending. They can change things like how far the ram goes down or where the back gauge is while the machine is running to avoid errors and waste as little metal as possible.
Operators who do not have much experience might not notice small problems with how the machine is lined up or know when to make adjustments. This can lead to many bad parts being made, especially when making a lot of them. Having experienced workers teach the newer ones the important steps for setting up the machine—like checking if the punch and die are lined up and looking at test bends—can help them learn faster.
Also, keeping easy-to-find notebooks or computer records of how to set up the machine for successful bends can help less experienced operators make accurate bends more easily. This directly improves how accurate the bending process is.
If the person operating the machine loads or puts the sheet metal in differently each time, it can change where the bend happens or the angle of the bend, which affects how good the final product is. Having standard ways of doing things, like always using the same starting point for loading the metal, is especially important for making these changes less likely.
When making parts that need more than one bend, it is especially important to always do the bends in the same order and use blocks that stop the metal in the right place to make sure it is accurate.
Using machines or robots to manage the parts can improve consistency because it takes away the differences in how different people might do things.
These robot systems need to be set up very accurately to make sure the robot grabs and moves the parts exactly as the press brake needs. This makes the bending process more consistent and reduces the chance of mistakes in each bend.
How accurate the press brake also depends a lot on putting the right information into the computer program.
The people operating the machine need to carefully check every setting—like the angle, how much extra to bend for spring back, and which tools to use—against what the job needs. They also need to make changes if the metal is thicker or harder than usual.
Mistakes when putting in the data are a common reason parts must be redone, and this can really slow down how efficiently things are made.
Regularly checking and cleaning up the computer system’s data, including deleting old job files, is especially important to avoid confusion and mistakes when setting up new jobs.
Many computer systems for CNC machines now have simulators that let operators evaluate and adjust how the bending will turn out and check for any crashes before they run the program on the machine.
If you lift sheet metal unevenly or let it slide across the edges of the die, it can really change where the bend is supposed to happen. Using supports, side stops, or special clamps can reduce the chance of mistakes caused by managing the metal by hand.
When working with excessively big parts, you might need several people to help or use machines to lift them to make sure they are lined up exactly right.
Also, using arms that support the metal from behind or using air-powered or hydraulic lifters can make it easier for the operators and help them line up the parts more consistently and accurately.
It is especially important, especially when bending big sheets, to make sure they do not rotate even a little bit while you are managing them because this can cause big mistakes in where the bend ends up. When more than one person is helping, having one person in charge to coordinate everyone’s actions can prevent accidental misalignment and make sure each bend is done very accurately.
People can make mistakes when using press brakes in diverse ways, like picking the wrong punch or die, forgetting to set up the machine after changing a tool, or not reading the job instructions correctly. Using checklists and clear standard ways of working can help reduce these risks by giving the operators a set of steps to follow.
If the order of bends is complicated, it can also easily lead to mistakes, especially if operators skip steps or do them in the wrong order. This can result in parts that have to be thrown away.
To make things less confusing and help people focus on busy workshops, using pictures of the parts and color-coding the tools can be extremely helpful.
Also, having regular training sessions to remind people of the right ways to do things helps make sure they do not forget important steps and stay careful about small mistakes that can add up over time and affect how accurate the bending is.
If you see that the bending angle is wrong while you are making a lot of parts, it is important to act quickly to stop more bad parts from being made.
Newer CNC machines that can measure the angle as it is being bent can automatically stop working if the angle is too far off. This really helps the operator step in quickly.
Talking clearly with your coworkers, like the people who check the quality of the parts, can help you figure out what is causing the error more quickly.
Having rules that allow operators to stop the machine right away if they see a problem lets them fix it before it leads to a lot of wasted material.
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Doing the same thing over and over can make operators tired or less careful, and they might not pay as much attention to vital details. Switching tasks from time to time or using machines to help, like automatic part feeders or robot arms, can help keep people focused and reduce mistakes made by humans.
Having operators check the angles and sizes of the bends regularly during the day or their shift helps make sure each bend is accurate.
Writing down the settings that worked well for a bend, like how far the ram went down, how big the die opening was, and any changes made to the angle, not only gives you something to look back at for future jobs but also means you don’t have to guess, which greatly lowers the chance of making mistakes.
Newer CNC machines make this even better by saving these settings on the computer, which makes things run more smoothly and helps make sure the bends are the same every time.
Also, keeping good records of how the machine is set up correctly—like how the back gauge is lined up, how far the ram is offset, and the crowning settings—is especially important for checking how well the machine is working. Some shops even keep a “job library” with pictures or drawings that show how to load the metal, what side guides to use, and what the final bending angles were.
The more complete and easier to find this information is, the faster and more accurately operators can do the same bends again or figure out problems with specific bending steps, which makes the entire process work better.
Changes in temperature can slightly change the size of the machine and change how the metal acts, especially how much it springs back. To stop this from happening, it is important to keep the room at a steady temperature or to change the bending settings when the temperature changes so the bending angles stay the same.
In real life, some workshops watch how the temperature changes each day to see if it affects the bending angles, especially when it is extremely hot or very cold. Also, warming up the hydraulic fluid in the system when it is cold can help keep it working consistently, which makes the bending more reliable. Paying attention to these trivial things helps reduce the effect of temperature on bending metal.
If the air in the workshop is damp, it can cause rust on the metal sheets and tools. This rust can make more friction when bending, which might change the bending angles. To stop this, it is a clever idea to keep the dies and the metal in a place where the humidity is controlled. This helps keep the surfaces consistent, which is especially important for accurate bends.
Doing regular things to prevent rust, like wiping down the tools and putting on rust protection, not only makes the equipment last longer but also helps keep the tools the right size for accurate bending. Keeping the table of the press break free of rust is especially important because it affects how the sheet metal sits when it is being bent, and even small tilts or slips can change the final product.
If there are vibrations in the workshop, often from other heavy machines nearby like stamping presses, it can affect how the press brake is lined up or how stable it is.
Over time, these vibrations can make bolts come loose or move the measuring tools out of place, which can slowly make the machine less accurate. Regularly checking the machine to make sure all the screws and bolts are tight, and the machine is stable is especially important.
Putting pads or special mounts under the press brake can help reduce these vibrations. Also, regularly checking if the back gauge is still lined up correctly is important to make sure the vibrations have not moved it.
If there are strong sources of vibration nearby that cannot be moved, trying to do the most important bending jobs when those other machines are not working as much can help reduce the effect of the vibrations and keep the bending accurate.
If the lights are bad, it can be hard to read the measuring tools and to see small problems on the surface of the metal. To fix this, putting up bright lights that spread evenly over the press brake helps operators see small bends or flaws on the metal before they bend it.
This kind of lighting helps stop mistakes caused by shadows or bright spots that might make it hard to see the important lines on measuring tools.
Good lighting not only helps you put the metal sheet in the right place but is also especially important for checking if the part is lined up correctly, especially when using press brakes that are controlled by hand and do not have computer precision.
If the bending angles are programmed wrong or if you forget to think about how much the metal will spring back, the parts might not be within the allowed range of error.
Newer CNC press brakes let operators make exceedingly slight changes to how far the ram goes down, so they can adjust the bending angles while it is happening. Setting the depth correctly is especially important, especially in air bending where the space between the punch and die really changes the final angle.
Bending a test piece with each new group of metal to see how much it springs back is an effective way to reduce waste. Operators should make changes for the usual differences in the metal and how the machine is working, carefully adjusting how far the ram goes down to get accurate bends.
If a part has a complicated shape, you often need to bend it in a specific order to avoid hitting other parts of the metal and to make sure the final shape is right.
If you bend in the wrong order, earlier bends can get in the way of later ones, changing the angles you wanted and bending the part out of shape. Using computer software that shows you how the bending will happen can help you plan and see the best order for bending complicated parts, making sure each bend keeps the whole piece in the right shape.
Even though some CNC machines can suggest the best order for bending, it is still important for the operator to check it.
Doing practice runs with cardboard or thin sheets of metal is extremely helpful for making sure the planned bending order will work before you start making the real parts.
Parts with complicated shapes or many edges sticking out can cause problems that regular clamps or back gauges might not be able to manage well, which could lead to the part bending out of shape.
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Using special holders or custom measuring tools can make bending complicated shapes more accurate. For example, bending tall edges might need tools that have more space or special shapes to avoid hitting other parts.
Also, parts with thin edges can be bent more accurately if the back gauge has special fingers that can be adjusted for height to make sure the part is in the right place. For things like complicated brackets or boxes, doing some of the bends partway or bending them a little bit before the final bend can help keep the angles accurate throughout the entire process.
To make sure the press brake is accurate, operators might bend the metal a little too far on purpose to make up for spring back and then adjust the settings for the next parts.
Bending by just 1 or 2 degrees more than needed can help with metals that are very springy or hard, making the bend more accurate. Also, bending a little less than needed and then bending more slowly to the final angle can help waste less metal, but it might take longer.
Newer CNC machines help with this by saving tables that show how much to correct the angle for diverse types of metal, which makes the process easier. But you must be careful not to bend too much because it could stress or crack the metal. This means you need to control it carefully and measure while you are making these adjustments.
If you do not use enough force, the metal might not bend all the way, or it might bend unevenly. If you use too much force, it can damage the tools or the part you are making.
Operators should use automatic calculators or look at the machine’s built-in charts to find the right amount of force for the type of metal they are using. This helps make sure the bending is accurate. It is also important to double-check the force shown on the machine’s screen with calculations you do by hand, like using standard charts that show how much force is needed for bending.
Especially when you are using all the force the machine can manage, understanding the minute details of setting the force can help prevent problems like the machine bending too much or the pressure changing unexpectedly, which can make the bend not as good.
If you do not line up the part correctly when you flip it over or turn it around, it can really change the starting points for the next bend, and these small errors can add up and affect the final size of the part.
To make these mistakes less likely, you can put marks on the part that you can use to line it up the same way each time or use special stops that hold the part in the right place. For complicated or big parts, marking the bend lines or using different colored edges can help operators keep track of which way the part is supposed to go.
Also, using tools that support the part from the side can keep it steady while you are moving it and stop it from tilting. In situations where you need extremely high accuracy, quickly measuring the part after you have moved it can confirm it is lined up correctly, so you can fix any problems before you make more bends.
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If the metal slides around while it is being bent, it really messes up how accurate the press brake is, especially with big or heavy pieces.
If the surfaces are too shiny or oily, the metal is more likely to slip, which causes bends that are not right. Using surfaces that are not slippery or putting clamps on the back gauge can really help hold the metal in place.
For metals like shiny aluminum, which tend to move easily, you need clamping systems that have rollers or special grippers. But you must set them up carefully, so they do not dent the metal.
Watching the metal closely, either by eye or with sensors that can tell if it is slipping, is especially important. It lets the operators know if the metal moves when it should not during the bend, so they can make sure every angle is exactly right.
Newer CNC press brakes can follow complicated programs with many steps. But if there are any mistakes in the program, they can cause problems throughout the whole bending process and make the final part inaccurate.
Using tools that show you how the bending will happen on a computer or programs that help you write the bending instructions can really reduce these risks. They can show you if anything might crash and help you adjust for any angle differences ahead of time.
Operators should make sure every line of the program is correct and check if it works by bending some test pieces. Programs that show the whole bending process in 3D make this even better by showing you if any part of the metal will hit the machine while it is working.
Also, some CNC machines can automatically change the bending program based on adjustments that the operator makes while the machine is running. This helps make sure the bends are consistent every time you make the part.
Using internet-based systems can make this even easier by letting you share the best bending programs between different machines. This helps everyone use the best ways of doing things.
If the computer programs used for designing (CAD), planning (CAM), and controlling the machine (CNC) do not work well together, it can cause mistakes in understanding the shapes or how much to bend, which affects how well the press brake works.
To make sure they work together, you need to save designs in common file types like DXF and carefully check settings like how curved the bends will be and other factors in each program. If these settings are different, like how much to subtract for the bend, it can make the final part the wrong size.
Regularly updating the software and making sure the people who design the parts and the people who run the machines talk to each other are especially important steps to make sure all the computer tools match what is happening when the metal is being bent.
If the press brake’s controls do not have features that can guess how the metal will act, it means the operators must do more work by hand to adjust for things like springback. This can take more time and effort to set up accurate bends.
Better control systems that can predict how the metal will react when it is bent can automatically change how far the ram goes down. This means operators do not have to do as much testing and adjusting by hand. Without these features, operators must use their experience and test over and over to get the right angles, which can be slow when you are making various parts all the time.
Using systems that can correct the bending angle as it is happening can really speed up setup times and make production better, especially when you are making custom parts or small batches.
Putting in systems that give you live information about the bending angle while it is happening really changes the bending process. It lets you amend how far the ram goes down or if it is tilted right away. This is helpful when working with metals that tend to spring back a lot, like stainless steel or extraordinarily strong steel.
These live feedback systems often stop the press brake when it is close to the final angle so you can make exceedingly small adjustments based on exact measurements. This makes sure every part meets the strict accuracy rules.
But it is especially important to take care of these systems. The sensors need to be kept clean and set up correctly to work right.
Using robots and special machines to move parts around makes sure the metal is managed the same way every time. This is especially important for getting the same accurate bends over and over, especially when you are making a lot of parts or parts with complicated bends.
When robots load and unload the metal sheets, each piece is put in exactly the right spot, working perfectly with the press brake’s settings. These robot systems are not simply great for putting the metal in the right place; they can also measure the parts after they have been bent. This lets the machine amend the computer program right away, making sure every bend that follows meets the strict quality rules.
But for the robots to work well, their movements need to be set up very accurately, and the robot arms need to be checked regularly to make sure they are not out of line. If they are not lined up correctly, it can cause mistakes when bending parts that need to be bent more than once.
Checking every day that the oil levels are right, the parts are clean, and the clamps are tight helps stop small problems from becoming big ones that can make the bending less accurate.
Replacing important parts like seals and filters before they break down helps keep the hydraulic or motor systems working reliably, which is important for the machine to work the same way every time.
Also, keeping good records of all the maintenance that has done helps you see if certain parts are wearing out quickly or if the same problems keep happening. This can show that there might be bigger issues that need more serious fixing.
Checking once a year if the machine is still level is also especially important because even slight changes in how the floor is can affect the shape of the machine’s frame, which can make the bending less accurate over time.
The people who make the machines might suggest setting them up correctly (calibrating) at various times, like once a month or every three months. It depends on how many parts you are making and how accurate they need to be.
When you calibrate the machine, you should check if the top beam (ram) and the back gauge are lined up correctly using precise measuring tools. You also need to make sure the numbers shown on the machine’s screen match the real positions of the parts.
If you are making parts that need to be exactly accurate, like parts for airplanes or medical equipment, you might need to calibrate the machine more often.
Writing down every time you calibrate the machine gives you a helpful record. This can help operators see if the machine is starting to lose accuracy over time, which might mean it needs more thorough maintenance, or someone needs to investigate bigger mechanical problems.
This means looking at all the moving parts, the rails that guide the movement, the wires that control things, and all the screws and bolts to make sure everything is tight and lined up correctly.
The stress of using the machine regularly and shaking from other machines nearby can make screws and bolts come loose and change how things are lined up. This can slowly make the bending less accurate.
Making sure the measuring tools are clean and do not have any dust or dirt on them helps the machine know exactly where the parts are, which is especially important for accurate bending.
Also, for machines that have a crowning system, it is important to check that all the hoses and connections for the hydraulic fluid are tight and not leaking. This helps keep the pressure even along the whole bend.
Putting the right kind of oil or grease on the rails that guide movement, the points where parts turn, and the sleeves that the ram moves in helps reduce rubbing and stops them from wearing out too quickly. This is especially important for keeping the bending accurate for a long time. Automatic oiling systems are extremely helpful because they put oil on the parts regularly at set times, which keeps the machine working its best.
Choosing the right type of oil or grease for how hot or cold the workshop helps keep it the right thickness, which is important for the machine to work the same way all the time.
But operators need to be careful not to put too much oil or grease on because extra can attract dust, which can mix with the oil and make a gritty paste that can damage the machine.
Cleaning the machine regularly to get rid of this buildup is just as important as putting on the oil or grease. Newer machines have sensors that watch how much oil or grease is flowing and what the pressure is. This helps them tell the operators if there are any problems like clogs or leaks, which keeps the press brake working well.
Over time, the shaking from using the machine and pressure from outside can make important bolts come loose. If you do not check them, this can change how the machine is lined up and make the bending less accurate. Important places to check often are where the ram connects to the cylinder, where the back gauge rails are held up, and the beams that go across the frame because these areas have the most stress.
Using special glue for screws or washers that lock in place in these areas that shake a lot can really help keep the screws and bolts from coming loose.
When you check the machine, it is also especially important to look for any cracks or bends in the metal parts or where they are welded together because these can also affect how stable and accurate the machine is.
If things like rust or small pieces of metal build up on the tools, it can stop the metal from flowing smoothly when it is being bent. This can make the parts the wrong size and cause scratches on the surface.
Regularly cleaning the surfaces—by just brushing or wiping them and using stronger cleaners if needed—helps keep the bending surfaces in decent shape. Also, if you are bending metal that has a sticky film or a protective layer on it, you need to make sure all of it is completely removed so the opening in the die is the same everywhere.
It is just as important to clean the tips of the punches regularly. Keeping them free from dirt and small pieces of metal stops unwanted lines from appearing on the finished parts and helps keep the bending angles consistent.
Calculating exactly how much extra length you need to add for the bend and how much to subtract is especially important for getting the right sizes for the finished parts. If you use the wrong formulas or forget to consider the K-factor for the specific metal you are using, it can make the final parts quite different from what you wanted.
Usually, when you use CAD/CAM systems, the computer does these calculations for you. But how accurate those calculations are depending a lot on whether the operator puts in the right information. Diverse types of metal, like different grades of steel, can change the K-factor or how much you need to subtract for the bend, so you might need to change the settings in the program.
To make things more accurate, it can be helpful for operators to keep a list of K-factors that they have evaluated for the metals they use most often.
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When parts have tricky edges and bends that do not go all the way, you need to bend them in an extremely specific order to avoid hitting other parts or bending them out of shape. Using computer programs that show the bending in 3D is especially important. These programs can help you find and fix problems before you even start bending the metal.
For parts that have edges that bend inwards or backwards, you often need to use special tools shaped like a gooseneck to keep the tools from hitting each other. Also, even if you miss a small detail in the design, like a little bump sticking out, it can hit the punch too early and cause the bend to be wrong.
To make these problems less likely, it is important for the people who design the parts and the people who operate the press brake to work together and review the designs. This helps them find and fix any problems with how the parts are designed before they start making them.
Using methods like laser or plasma cutting can make the edges of the metal hotter, which can change how hard the metal is and might affect how it bends.
It is especially important that things you do before bending, like cutting small notches or making holes, are lined up exactly with where you plan to bend the metal. This helps keep the final shape accurate.
Making sure the cut edges are smooth and do not have any rough bits is especially important because rough edges can catch on the die and cause mistakes. Also, if you put holes too close to where you are going to bend, it can make the metal weaker or bend in the wrong way.
Sometimes you need to make slight changes, like moving a notch a little bit, to make sure the bend happens in the right place and to avoid angle mistakes in complicated parts.
Doing a quick test bend on a small piece of metal can help you make sure you know how much the metal will spring back and how much force you will need before you start making all the parts. This is important because the metal might act a little differently in real life than what the numbers say.
Having a way to check the metal when you get a new roll or sheet, by evaluating a standard piece, can show you if there are differences in how strong or how thick it is. These differences could change the bending angles.
Writing down the results of these tests helps make the computer programs for the CNC machine or the offline programming better at guessing how the metal will bend, which makes the bending process more accurate overall.
Making sure the metal in each batch is consistent is important for accurate bending. If the thickness or hardness changes even within the same batch from the supplier, it can make the bending angles different. Writing down any changes you make for a specific batch helps operators keep the quality the same even if the metal is a little different.
If the metal suddenly starts acting very differently while you are in the middle of a job, the operators need to be able to stop the machine and change the settings to deal with these changes. Putting labels on smaller groups of metal sheets helps you keep track of these differences and make the right adjustments.
When people work for a long time, they can get tired and not pay as much attention. This can make them more likely to line things up wrong or set the gauges incorrectly, which is especially important for getting the right bending angles. Doing things like switching tasks, using tools that make the job easier on the body, and using mats that help with tiredness can reduce mistakes caused by being tired.
Also, having good lighting and short breaks scheduled can really help people stay focused. Using machines that do some or all the bending automatically reduces how much physical and mental effort the operators need to put in, which makes the bending process more consistent.
The people in charge might also watch how many parts are being rejected during the day to see if there is a connection between how tired the operators are and how many bad parts are being made. This can help them plan work schedules and how much work needs to get done better.
Every time you put in a new punch or die, you need to line it up very carefully and evaluate it to make sure the machine can still bend accurately.
If you do not have a consistent way of changing tools or if you do it too quickly, it can lead to small mistakes that add up and affect all the parts you make. Using quick-change tool systems that have good locking parts can really speed up setup times and reduce the chance of mistakes.
Also, doing a quick test bend after changing a tool makes sure everything is still lined up right. Writing down the last known settings for each set of tools makes it faster to set up the machine for future jobs, making the changeover easier and keeping the bending consistent.
When the press brake is working hard, it can get hot, which can change how the machine works because the parts expand, and the bending angles can change. It is especially important to control this heat to keep the bending accurate.
Things like planning breaks for the machine to cool down or spraying coolant on it can help with accuracy problems caused by heat. Watching the temperature in important places, like where the die touches the metal, lets operators know when they need to let the machine cool down to keep the bending consistent.
When you are making a lot of parts out of thick metal, the heat can make the machine’s table expand quite a bit, and you need to consider this when you are setting up the bending process.
Understanding the diverse types of press brakes and how their specific features influence accuracy is essential for optimizing production in metal fabrication. The primary types include electric, hydraulic, hybrid, and manual press brakes, each with unique attributes that affect performance and precision.
CNC press brakes stand out for their ability to automate the bending process with precision. These machines can achieve repeatability within a few thousandths of an inch, courtesy of sophisticated computer-controlled systems that adjust ram depth and back-gauge positions accurately.
Enhanced features such as in-process angle measurement and automatic crowning adjustments help maintain consistency across varying material properties and thicknesses, significantly reducing setup time and human error. The integration of CNC technology allows for complex bending operations that require elevated levels of precision and repeatability.
Hydraulic press brakes are favored in settings where heavy-duty bending is required. A hydraulic press brake can maintain consistency and power across large batches and thick materials.
Accuracy in hydraulic systems is augmented by technologies like synchronized cylinders and CNC controls, which manage the precise movement of the ram.
Regular maintenance and calibration are vital to ensure long-term accuracy, addressing potential issues like hydraulic fluid viscosity changes or part wear that could otherwise impact performance.
An electric press brake utilizes servo motors to achieve extremely precise ram positioning, crucial for high accuracy in bending operations. These machines offer a repeatability of ±0.001″, making them highly dependable for tasks requiring stringent tolerances.
Electric press brakes are not only known for their precision but also for their energy efficiency and lower maintenance costs, as they do not require hydraulic fluid changes.
The absence of hydraulic components reduces the risk of fluid leaks, further enhancing their operational reliability and consistency in maintaining bending accuracy.
Key advantages include:
Manual press brakes demand an elevated level of skill and experience from operators, as they lack the automated control systems found in more advanced machines. The accuracy of manual press brakes depends on the operator’s ability to consistently position and reposition the workpiece accurately.
These machines are typically suited for low-volume production or workshops that manage simple bending tasks.
Challenges include:
Hybrid press brakes represent a synthesis of hydraulic power and electric precision. They use servo motors to control hydraulic pumps, combining the force capacity of hydraulic systems with the accuracy and efficiency of electric systems.
This type allows for precise control over the bending process, particularly useful in applications involving variable material properties and thicknesses.
Benefits of hybrid press brakes include:
It is especially important to measure how accurate a press brake is to make sure the bending process is precise, which is key in making metal parts.
There are diverse ways to check how accurate press brakes are, and each way helps make sure the machine is working as well as it can and that the final parts meet strict rules.
The easiest way to check how accurate a bend is to measure the angle of the bent metal. Tools like very precise protractors, digital angle finders, or laser systems are used to see if the bend angle is what it is supposed to be. For example, if you want a 90-degree bend, you measure how much it is different from 90 degrees. Usually, the allowed difference is between half a degree and one degree.
It is especially important to check if the lengths of the bent edges and other straight measurements are correct. This is often done with tools called calipers or with more advanced machines called coordinate measuring machines (CMMs), which give exactly accurate and consistent measurements.
Doing test bends on scrap metal or pieces made just for testing is an effective way to check the machine’s settings before you start making all the real parts. This helps you see if there are any differences between what the machine is set to do and what it does, so you can make changes before the final production.
Repeatability means how well the press brake can make the same bend over and over when everything else is the same. You evaluate this by doing several bends and measuring each one to see if they are all the same. CNC press brakes usually keep track of these measurements, which helps you adjust make the bends even more consistent.
Following rules like GB/T-, you can bend special test pieces that have specific lengths and thicknesses to see how accurate the machine is working. The results of these tests are written down and compared to the allowed limits.
For bends that are long, you often check if the bend line is straight by using a straight ruler and a feeler gauge (thin pieces of metal of different thicknesses). This helps you see if there is any bending in the machine’s table or the punch that could make the bend inaccurate.
Some places figure out the overall accuracy of the bending by looking at different things like how much the angle is off, how accurate the straight measurements are, and how consistent the bends are. This gives a better idea of how well the machine is working.
Especially when you need very precise parts, measuring how curved the bend is compared to how curved it is supposed to be can show you how well the machine can manage diverse types and thicknesses of metal without making mistakes.
Making a press brake more accurate needs a few things: taking care of the machine, setting it up exactly right, and having skilled operators.
Here are nine things you can do to really make bending metal more precise:
Getting exactly accurate bends with press brakes is super important for businesses that need metal parts made to exact sizes. Here is how you can keep the bends very precise:
Keeping press brakes exactly accurate does cost some money, but the good things you get often make up for it:
Getting accurate bends from a press brake is not just about having fancy machines; it is about everyone working together to do an excellent job.
Keeping this accuracy means you need to be ready and act. This includes setting up the machine correctly on a regular basis to keep up with the different things you need to make with metal. It also means carefully checking the machine to find problems before they get worse.
So, to sum up, making sure press brakes are accurate is not just about the machines themselves. It is about really trying to do things precisely, keeping everything updated, and having skilled people manage the machines. This makes sure you get the best quality parts, and the work gets done efficiently.
You should always oversize the press brake capacity by around 20 – 30% with respect to your data in order to allow for the variability in the characteristics of the metal and so that you are not in danger of working to the limits of the machine’s capacity.
One of the most common misjudgements is to confuse the total force needed to bend a given sheet metal part with the tons per metre for the specific thickness, material and die. Find out more in this guide.
Clearance is simply the front opening of the press brake. A press brake with a larger stroke is a machine equipped with greater intermediates that allow easier extraction of the bent parts.
Different metals have varying properties and behave differently when subjected to bending. For instance, aluminum is generally more malleable than stainless steel. Understanding the characteristics of the specific material you’re working with is essential in determining the appropriate press brake and bending parameters.
Our Ultimate Guide to Sheet Metal Materials provides expert insights and practical advice. Explore now to choose the perfect material for your project.
Complex press brakes offer advanced features and automation, but they often require skilled operators. If your team lacks the necessary expertise, consider the time and resources needed for training. Weigh the benefits of increased capabilities against the potential challenges of operator training and maintenance.
There are many different types of press brake machines. Each of these comes with its own set of advantages and limitations. You can choose the right press brake based on your use case. These different types of press brakes are:
Mechanical press brakes: These are the most basic type of press brake and are generally the most affordable. However, they are also the least versatile and can be difficult to operate precisely.
Hydraulic press brakes: These are the most common type of press brake and offer a good balance of power, precision, and versatility. They use hydraulics to power the ram, which allows for more precise control over the bending force.
Pneumatic press brakes: These are a good option for lighter-duty bending applications. They are quieter and faster than hydraulic press brakes, but they also have less bending force.
Servo press brakes: These are the most precise type of press brake and are a good option for high-precision bending applications. They use servo motors to power the ram, which allows for very precise control over the bending position and force.
CNC press brakes: These press brakes are computer-controlled and can automate many of the bending tasks. They are a good option for high-volume production runs or for complex bending jobs.
Hybrid press brakes: These combine the power of hydraulics with the precision of electric motors. They are a good option for applications that require both high precision and high bending force.
Tandem press brake: particular configuration that involves the connection of two machines into one, but there are also solutions that combine three bending machines (tridem) or 4 bending machines (quadrem). Read our guide on "What to know before choosing a tandem press brake".
Intermediates are adaptors to insert between the beam and the punches and are very useful because they allow deep box structures to be easily made.
The tool clumping systems are sub-divided into:
manual locks;
semi-automatic locks:
pneumatic blocks;
hydraulic locks;
The choice of correct locking is fundamental to reduce the work times and correctly manage the work zone.
It is a manual semi-automatic lock with rapid front locking-unlocking system of the punch. Operation is very simple and, compared to the traditional manual solution, allows faster and easier re-equipment of the machine.
In fact, by moving the locking lever, the punch is released to remove it from the front; while, on closure, the punch is automatically brought to stop and perfectly aligned.
The automatic tool locking systems allow equipping of the press brake in complete safety. The tools are automatically aligned, positioned and fastened. This solution drastically reduces the equipping time and considerably increases production.
Today, a modern and innovative solution exist that allows automated change of the punches and matrixes. For example, VICLA hybrid press brakes can be connected to an automatic tools warehouse that allows equipping, even on multiple stations, of higher and lower tools.
This system is customisable and designed to measure according to client requirements; it reduces setup by 4 or 5 times compared to manual tasks and automatically performs even the most complex equipping, managing 70 mm wide V matrices, rod holding tools and allowing the tool to rotate 180°.
Automation covers everything, including upstream operations. One of the more interesting aspects is programming by the technical office: the CAD/CAM system processes the three-dimensional file, creates the best bending cycle and sends the program to the machine that is automatically equipped, referencing the bending sequence directly on the numerical control. All tooling and machining data are automatically saved at the end of the work and exported to management for a 4.0 key data analysis.
The rear gauge is a motorised structure on which the references are set and can be moved and positioned to allow a variety of complex bends.
Movement of the back gauge along the depth of the machine is called axis X. Vertical lifting is called axis R.
It consists of very important and useful tools to support thin sheets. They are equipped with pneumatic operation and a Teflon coating that prevents marks on the material. They can also be activated by numerical control. There are 2 references and they are usually manual, but they can be automated and controlled directly by the CNC; the positioning of the stops is along the Z axis.
All towers are equipped on VICLA press brakes with a visual LED stop. Switch on of the LED ensures contact of the sheet with the reference.
In more accessorised versions, the towers are:
The greater the length of a bending machine, the more the problems relating to the structural failure of the bench, making it more difficult to get a well worked part. Over the years, technological evolution has taken giant steps, passing from manual systems (such as using paper shims under the matrix) to automatic, mechanical or hydraulic systems, where a pre-load of the assumed deformation was determined. The limit of these systems is based on a theoretical calculation set by numerical control.
VICLA has developed an intelligent system that improves the work in the workshop: the active Clever Crowning system.
Thanks to special sensors in the beams, crowning enables measurement and compensates deformations in real time. There is no need to set any data; the system actively reacts to changes in characteristics.
Each press brake, despite its robustness, is subject to structural bending, during the bending phase, and obviously the deformations are much bigger the greater the effort the machine has to make.
The main deformation is crowning, which corresponds to bending of the beam which is pushed into position by the side cylinders; the other (and for many reasons semi-unknown), is called in jargon “yawn” and is the tendency of the frames to open in the throat zone.
Thanks to the Flex system the sheet metal press brake dynamically compensates any deformations based on the effort required: the CNC receives the data from the pressure sensors of the cylinders, which are interpolated in real time to establish the correction to implement.
It is not enough to just add an inverter to call a press brake "hybrid"; in fact, technological innovation revolves around a specific hydraulic system, which in the case of the standard hybrid model, includes a completely independent dual hydraulic circuit, each equipped with its own tank, motor, pump and inverter.
The functional separation of the two cylinders allows optimised control according to the load required for each cylinder; moreover, it allows efficiency to be achieved in terms of energy.
It is a system able to minimise wear of the machine by concentrating all its efficiency and automatically balancing the working pressure exclusively on the side that is used during bending of that specific part.
A further level of performance is provided by the Hybrid Plus model: the system consists of a brushless motor for each cylinder, capable of providing high forces and high movement speeds. It is an even more compact system consisting of a direct drive motor and pump, installed directly on the cylinders. with significantly reduced piping.
The results in numbers of this technological innovation are significant, as seen on the graph.
V-Control consists of two laser sensors mounted on linear guides that slide to the rear and front of the press brake bench taking the measurement in one or three points depending on the length of the piece. Located on the sides of the matrixes, they have the purpose of reading, through a system of lasers and cameras, the inclination of the edges of the bends during deformation.
It is the most complete and performing solution for automatic angle measurement and control.
Angle reading takes place in 3 phases:
A laser beam is projected on the sheet metal surface
The camera detects the elastic recovery of the material
The CNC automatically sets the correction suitable to obtain the system desired angle that we use on our VICLA press brakes and is the best you can find on the market. The guaranteed precision is very high and in the order of fractions of a degree.
The system is also able to historicize the elastic recovery of the sheets, ensuring a constant and specific self-learning of the press based on the real situation of the company. Obviously the angle control system guarantees the best performance if it is supported by solid and precise mechanics and perfect integration with numerical control.
With the latter, there is a continuous data exchange dialogue that allows perfect application with each item being processed. If, for example, for volume issues, a specific bend cannot be measured by the angle control system, it can be "linked" to the previous reading made on another flap of the same piece.
Vicla angle control is a safe investment and surprisingly quick return as it makes continuous measurement operations by the operator completely unnecessary with an exponential increase in productivity and quality.
There are essentially three types: inserts in the punch, hosted in the matrixes or applied to parallel sliding trolleys the exact same as those of the optical systems and placed on the sides of the bench.
On first examination, it could appear a definitive solution, however these are also not without limitations which, in practice, only appear during their real use.
The first is without doubt the installation difficulty. This is the typical limit of the controls inserted in the tools that include use of special punches and matrixes equipped with sophisticated, sensor-based strips.
Such angle control systems have very poor versatility when you consider they are not usable by changing tool set-ups.
Another limitation is their characteristic fragility.
Being small and very sophisticated mechanical elements, they are easily subject to failure caused by accidental impacts or malfunctions due to the accumulation of dust and dirt.
Optical control is directly assembled on photocells to capture images of the profile detecting, calculating and correcting the bending angle.
One of the most sophisticated optical controls is the IRIS PLUS system. Although it is part of the optical angle control unit, IRIS plus is an alternative solution because it can perform an extremely accurate reading during the bending phase while remaining at a safe distance from the work area.
This eliminates any interference between the parts and the angle control devices and achieves totally versatile use.
The system, in fact, allows very interesting accuracy and reliability if the emitter and the receiver are not beyond a certain distance.
After approximately 2.5 metres, in fact, there is a natural increase in the phenomenon of refraction of light rays that reach the control system which are not sufficiently clear. The "noise" can be reduced by decreasing the sensitivity of the system but with the consequence of not ensuring the same accuracy in the reading of the bend.
The bottom bed has a bending/flattening table in order to perform flat hem bends without the need for a dedicated die. Its versatility makes it the ideal solution for companies that carry out many flat hem bends. The option is built directly into the die holder, and therefore can be used in conjunction with any other die that has a standard connection without the need to disassemble the table.
These front supports have a linear guide that extends beyond the bottom beam. Their height can be adjusted and they also slide sideways and rotate. A practical clamp-release system makes them very easy to mount and remove quickly.
They can lift weights up to 380kg. Use of the metal sheet bending followers offers an important advantage to reduce risks for the operator and increase the quality of the bent parts: it was designed to avoid counter-bend effects and reduce the need for other operators. It can also be easily removed from the front and placed on another bending machine.
An extension of the linear guides, extending beyond the bench. This solution is used to park the sheet metal supports when not in use.
It is powered by an integrated solar panel that allows you to get up to 20% more autonomy from battery life; it does not require connection, nor cable laying. The ultrasonic sensors are located on either side of the lower bench to transmit and receive data wirelessly.
The system indicates via the incorporated LED the right locking position of the equipment during tool configuration and indicates the position of the active tool in production mode.
It is a real and proper visual aid immediately available to the operator who, by doing so, does not waste time measuring and understanding where to position the tool and can dedicate his time to other operations.
For more information, please visit Electric Servo Press Brake for Accurate Bending.