THE INTERPLAY OF FORCES IN A BOLTED JOINT
| Figure 1 | Figure 2 |
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In simple terms, there are two possible types of static load in a bolted connection:
- Without a clamping force – the force is transmitted between the plates by bearing forces and shear forces in the body of the bolt or the thread. The plates being connected move relative to each other until the bores bear against the body of the bolt or against the thread. In this case, the bolts are loaded in shear through transverse loading; see figure 1.
- With a high clamping force – the clamping force prevents the clamped parts from being displaced. The force is transferred by friction, and the bolts are loaded in tension through an axial load; see figure 2. For stainless steel joints, see our guide on preventing the seizing of stainless steel fasteners.
ELASTIC RESILIENCE OF A THREADED JOINT
- The bolts and connected parts function as an elastically resilient unit. The clamped elements are compressed elastically, while the bolt stretches during assembly. If the bolt stretches further due to an external load, the clamped parts spring back.
- The tensile force in the bolt is equal to the compressive force acting on the clamped elements, as illustrated in figure 3.
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A MORE ELASTIC BOLT CAUSES A SMALLER INCREASE IN BOLT LOAD
IN SHORT
- The structural members should be as rigid as possible.
- The clamping force should be as high as safely possible and should remain greater than the external separating load.
- More elastic bolts can be used. Choose a high clamping length-to-diameter ratio of at least 5×D, select a longer threaded length where appropriate and, when necessary, use a reduced-shank bolt. For dynamic connections, see our guide to fastener locking methods.
BOLT JOINT DESIGN PARAMETERS
| Design Parameter | Effect on Bolt Load | Effect on Clamping Force | Recommendation |
|---|---|---|---|
| More elastic bolt with a longer L/D ratio | ↓ Reduces additional bolt load Fsa | ↓ Greater clamping force reduction Fpa | Use a clamping length of at least 5×D. |
| Rigid clamped materials | ↓ Reduces additional bolt load Fsa | ↓ Greater clamping force reduction Fpa | Use rigid materials such as steel or cast iron and avoid soft gaskets where possible. |
| Higher preload Fm | No change to the Fsa amplitude for a given joint stiffness | ↑ Higher residual clamping force Fkr | Where the joint design and tightening method allow, tighten to approximately 90% of the bolt proof load. |
| Reduced shank diameter | ↓ Makes the bolt more elastic | See “more elastic bolt” | Use purpose-designed reduced-shank bolts. Where appropriate, a partially threaded bolt such as DIN 931 can provide a longer unthreaded shank than DIN 933. |
| Longer threaded length within the clamping length | ↓ Makes the bolt more elastic | See “more elastic bolt” | Select a longer threaded length where the joint design and thread engagement requirements allow. |
| Soft gaskets or washers | ↑ Increases bolt load fluctuation | ↑ Greater preload loss over time | Avoid soft elements where possible. If unavoidable, consider disc springs and an appropriate locking method. |
| Dynamic or vibration loading | ↑ Fatigue risk increases | ↓ Risk of complete clamping-force loss | Apply a suitable locking solution, such as Nord-Lock wedge-locking washers or Spiralock thread forms. See our guide to locking methods. |
FREQUENTLY ASKED QUESTIONS ABOUT BOLTED JOINT FORCES
What is preload in a bolted joint?
Preload, identified as Fm, is the initial clamping force created when a bolt is tightened. It compresses the clamped parts and stretches the bolt, creating an elastic system that resists external loads. Without sufficient preload, external forces act more directly on the bolt, increasing the risk of fatigue failure. Insufficient or lost preload is associated with approximately 80% of bolt fractures in service.
Why do bolted joints loosen under vibration?
Vibration can cause micro-slip between the clamped surfaces, gradually reducing the clamping force or preload. As the residual clamping force Fkr decreases, more of each load cycle is transferred directly to the bolt as fluctuating stress. Once Fkr reaches zero, the joint can separate. Locking devices such as Nord-Lock wedge-locking washers or Spiralock thread forms help maintain preload under dynamic loading. See our guide to fastener locking methods.
How does bolt elasticity affect fatigue life?
A more elastic bolt can be achieved through a higher clamping length-to-diameter ratio of at least 5×D, a longer threaded section within the clamping length or a reduced shank. In the force-deformation diagram, the flatter bolt curve means that less of the external force Fa translates into an increase in bolt load Fsa. Because fluctuations in Fsa contribute to fatigue, reducing this increase can extend the fatigue life of the bolt.
What is the clamping length-to-diameter ratio and why does it matter?
The clamping length-to-diameter ratio, or L/D ratio, is the total thickness of the clamped material divided by the nominal bolt diameter. A ratio of at least 5:1 is recommended because it makes the bolt sufficiently elastic to accommodate external loading without excessive stress fluctuation. Short bolts with a low L/D ratio are comparatively stiff and transfer more of a dynamic load directly to the bolt.
How do I choose between shear-loaded and tension-loaded bolted joints?
In shear-loaded joints with transverse loading, force is transferred through the bolt body or thread bearing against the bore. This may require fitted bolts, close-tolerance holes or reamed holes. In tension-loaded joints with axial loading, the clamping force creates friction that prevents the plates from moving. Highly preloaded tension joints are generally more predictable, easier to design for fatigue and compatible with standard clearance holes. For corrosive environments, see our stainless steel fastener guide.
Last updated: 12 July 2026
RELATED PRODUCTS AND GUIDES
Related products
- High-tensile bolts in property classes 8.8, 10.9 and 12.9 — suitable bolt strength and proof load are essential when applying high preload. Bolt strength is determined by heat treatment; see our heat treatment guide.
- Nuts for high-tensile bolted connections — select a nut with a compatible property class and thread specification.
- Nord-Lock wedge-locking washers — designed to help maintain preload in joints subjected to vibration and dynamic loading.
- Search for reduced-shank bolts — a reduced shank can increase bolt elasticity and reduce fluctuations in bolt load.
- Disc springs and Belleville washers — suitable for applications where controlled elastic compensation is required.
Related technical guides
- Fastener locking methods — compare methods for maintaining preload and preventing loosening under vibration.
- Preventing the seizing of stainless steel fasteners — understand how friction, lubrication and installation conditions influence stainless steel joints.
- Heat treatment of fasteners — learn how heat treatment determines bolt strength, hardness and mechanical properties.
- Stainless steel fasteners — select appropriate stainless steel fasteners for corrosive environments.