Fastener Calculator | Torque, Preload, Threads

Preload is the invisible clamp force that are applied to the bolt so that the bolt is held at a stretch that is just below its proof load. Preload is necessary to ensure that the joint remains tightly against the dynamic loads that are placed into the joint during operation. If a person dont provide enough preload, then the external forces may pry the joint apart.

If a person provide too much preload, however, the person may begin to yield the bolt shank or strip the threads that are present in the boss. Torque is one of the method that can be used to control the preload that is established between the mating parts of a fastener assembly. Friction, however, is a variable in that the friction between those parts will change the amount of torque that is required to achieve the desired preload.

How to Choose and Tighten Bolts

The degree of thread engagement between the bolt and the tapped hole is another critical factor that will determine the strength of the joint. If the tapped hole is made of soft material, such as aluminum or cast iron, then the female threads may fail before the bolt begins to stretch. For instance, a person should use a thread engagement length that is 1.5 times the diameter of the bolt for steel nuts.

For 6061 aluminum alloy, however, the person should use a thread engagement length of 2.0 times the diameter of the bolt. Additionally, the grip length of a bolt can impact how well it achieves the desired preload; short grip lengths can cause the preload to scatter. Proof strength is a factor that will help to determine the maximum load that will be placed into a fastener.

Proof strength can help to ensure that a fastener of the appropriate strength are used for the load that must be supported by the joint. For instance, SAE Grade 5 fasteners has a proof strength of 85 ksi; such fasteners are used in general machinery. SAE Grade 8 fasteners have a proof strength of 120 ksi; these fasteners are used in compact joints, such as vise jaws.

Metric 10.9 fasteners have a proof strength of 830 MPa; such fasteners are used in high-load frames where space are limited. If a person does not use the correct fastener for the application, then the fastener will either be unnecessarily overbuilt or underpowered. The lubrication of bolts will change the torque that is required to achieve a preload; lubrication changes the coefficient of friction between the mating parts, which is also called the K factor.

For dry plated bolts, more torque will be required to achieve a specific stretch in the bolt. If oil or phosphate treatment is added to the bolt, the K factor will be lowered. For instance, the addition of oil can lower the K factor from 0.24 to 0.18; the reduction in the K factor will reduce the torque that is required to achieve the same preload by 25%.

A bolt calculator can be used to ensure that shop practices correlate to the target load for a joint; the calculator will account for the type of finish that is applied to the bolt and the specific K factor of the bolt. The joint styles that are used will determine the different priorities for the fastener. For instance, joints that use through-bolts and nuts will provide even clamp force throughout the joint.

Through-bolts will have a target preload of 70 to 80 percent of the proof strength of the steel stacks. For tapped holes, the first priority is to ensure that the threads are properly engaged. Studs are another alternative to through-bolts; however, washers must be used under the bolt head to even out the bearing pressure of the bolt head under the soft surfaces; this prevents the crush of the gaskets.

Thread series can change the way that a fastener performs. Coarse threads are more forgiving of the thickness of the mating parts; fine threads are better suited for thin sections of materials. However, fine threads are less resistant to vibration.

Bearing pressure is another important factor; the longevity of a bolt can be determined by the bearing pressure that is placed into it. One way to increase the area of contact between the bolt head and the mating part is to use a large washer. The larger area created by the washer will reduce the bearing pressure that is placed into the bolt head; for instance, if a 1-inch diameter washer is used under a half-inch bolt, the contact area will be quadruple.

This increased area will prevent brinelling of the aluminum housings into which the bolts are placed. There are a few mistake that people can avoid when using bolts. One mistake that should of been avoided is attempting to achieve 90% of the preload of the fastener without using calibrated tools.

Another mistake is using short grip lengths; short grips can cause the preload to scatter. A third mistake is not paying attention to the material of the tapped hole; cast iron can be brittle. Environmental factors can also impact a fastener.

For instance, thermal growth of exhaust manifolds will require the bolt to be looser in its torque targets. The vibration that is created by engines can cause issues with standard nuts; prevailing torque nuts should be used instead of standard hex nuts. Finally, shop air tools can add 10 to 20% more torque to a bolt than is targeted; using air tools with a low K factor lubricants can help to even this out.

Certain fastener grades are used in specific applications. A325 structural bolts are used in structures where the bolts will experience seismic movements; A325 bolts have a proof strength of 92 ksi and cannot be brittle. Stainless A2-70 fasteners are used in environments where the fasteners are exposed to water; they are corrosion resistant.

A2-70 fasteners, however, have a proof strength of only 65 ksi. Each of these fastener grades must be used in the correct type of ecosystem and in the specific load that is to be placed into the bolt. Presets can be used in determining the specifications of a bolt; presets can load the typical pitch of bolts, 75% of the preload target, and the standard K-factor of 0.20 for oiled bolts.

Reference tables can also assist in determining the size of the bolt that should be used in a specific application; for instance, reference tables can indicate that M6 covers will have a 1mm pitch, or that 3/8-16 UNC bolts are used for frames. Mathematical breakdown of bolts involves calculating the tensile area of the bolt. The formula to calculate the torque is torque equals the K factor times the bolt force times the radius.

To calculate shear strength, the formula uses the values of Pi, the pitch diameter, and the engagement length. The margin ratio of a bolt can indicate the risks of using that bolt in a design; a ratio of 1.1x means that a bolt must have more thread depth when used in soft threaded materials. If the preload specifications of a bolt are met, if the friction of the system is consistent, and if the thread engagement is correct, then the bolt will hold up to the abuse that is to be placed upon the bolt.