Over-torquing is a prevalent issue that can lead to costly repairs and downtime. This article provides an in-depth look at what over-torquing is, the typical causes behind it, and strategies for prevention. Understanding these aspects will help you maintain the integrity of your fastening work and avoid common pitfalls.
Torque, in physics and mechanics, is the rotational analogue of linear force, which is sometimes referred to as the moment of force, or moment for short. When driving a screw, torque is applied by the screwdriver rotating around its axis.
Over-torquing happens when the torque applied exceeds the intended limit of the transmission system. This issue can arise from abrupt load changes, operations during start-up or shutdown, severe mechanical wear, or errors in the system. Over-torquing is a serious problem as it can cause various issues such as damaging the fastener, stripping threads, or even causing structural damage to the component being fastened.
Although an impact driver looks like a drill, it’s not designed to drill holes. It works by using rotational force + bursts of impact + high torque levels to drive-in fasteners. The rotation normally works in a two-steps-forward, one-step-back pattern, with the bursts of impact up to 50 times per second when encountering resistance. This function makes an impact driver significantly more effective at driving in fasteners than drills. They are normally designed for fixing to timber substrates, as wooden fibers are a real force of nature and can sometimes be very tough to penetrate and clear through, which is why its burst of impact pattern is so effective.
For self-drilling screws, setting the correct torque is critical, especially when fixing sheets to metal substrates. There is an optimal rpm (rounds per minute) to create the most effective drill and drive process – too slow, and the screw will fail to penetrate, too fast, and the screw will burn out prematurely during the process.
(Read more: How to use self-drilling screws? Step by Step Tutorial)
Knowing when to stop is probably the most difficult yet most important skill of all when it comes to fixing any kind of fasteners. When fixing screws to different substrates, there are always signs, albeit often quite subtle, of when the substrates are joined properly. It normally requires basic knowledge and oftentimes a bit of finesse, experience, and practice to get it right.
A very simple point of reference when fastening screws with EPDM washers, is to first slow down when the EPDM washer comes in contact with the substrate below, make a full stop, and then gently tap the trigger a couple of times until the EPDM is compressed to the point that it almost flush / in-line with the screw flange. Go any further and you’re in over-torquing territory and run a huge risk of the EPDM washer being squashed and completely destroyed.
(Read more: 6 Benefits of Using Roofing Screws with Rubber Washer)
Ensure that personnel using the tools are adequately trained in the correct techniques. For example, the techniques for drilling a No. 5 point screw will differ from drilling a No. 3 point screw, or reduced point screws.
Pay attention to the material that the screws are drilling through, and affixed to. It is very common for personnel to focus on the material that the screws are drilling through, but unaware or even ignore the substrates that the screws are affixed to. For example, when fixing a 0.7mm metal roofing sheet to a 12mm metal substrate, a No. 3 point self-drilling screw is defenitely not cut for the job.
(Read more: How to Master Use of Self-Drilling Screws)
Check, and check again – the importance of routine inspection. This habit of constantly checking works in all kinds of situations. As a screw manufacturer, our screw machine operators not only have to do routine checks on the machinery during production, a very important part of their job is to do routing lot and batch checks of the screws themselves. It is never too late to check again to make sure that dimensions are within tolerance ranges.
By adhering to the basic principles outlined above, you can significantly reduce the risk of over-torquing and ensure the longevity and safety of your fastening projects. Implementing these practices fosters precision and care, minimizing the chances of damage to fasteners and substrates, and reducing costly repairs and downtime. As the user, you become a critical part of the solution, maintaining high standards and contributing to overall efficiency and success. Remember, prevention is better than cure; with the right knowledge and habits, you can ensure optimal performance and safety in all your fastening tasks.
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