Tempered glass is widely regarded as a “safe glass” and is commonly used in architectural, industrial, and equipment applications. While it does offer clear safety advantages over ordinary glass, its safety performance is sometimes misunderstood or overestimated when applied outside its proper use conditions.

One undeniable advantage of tempered glass is its fracture behavior. When broken, it shatters into small, blunt fragments rather than sharp shards, significantly reducing the risk of severe cuts. It also has higher mechanical strength—typically four to five times that of annealed glass—making it more resistant to impact and bending under normal conditions.

However, tempered glass is not immune to failure. One limitation lies in its sensitivity to edge damage. Even minor chips or scratches along the edge can destabilize the internal stress balance and trigger sudden, complete breakage. In many industrial applications, edges are exposed to vibration, clamping forces, or thermal gradients, increasing this risk.

Another often overlooked issue is spontaneous breakage. Nickel sulfide (NiS) inclusions, formed during manufacturing, can expand over time and cause tempered glass to shatter without warning. Although rare and controllable through quality processes, this phenomenon means tempered glass cannot be considered fail-safe.

From a thermal standpoint, tempered glass has limited resistance to extreme temperature gradients. While stronger than ordinary glass, it may still fail in applications involving rapid localized heating or uneven cooling, especially when compared to borosilicate or quartz glass.

There are also design and application constraints. Tempered glass cannot be cut, drilled, or resized after tempering. Using it in applications that require on-site modification or precise adjustment can create safety risks during installation or maintenance.

In addition, tempered glass does not always provide the best solution for pressure-bearing or corrosive environments. Laminated glass, borosilicate glass, or specially designed sight glass assemblies may offer more predictable and controlled failure behavior.

In conclusion, tempered glass is safe when used correctly, but its safety can be overestimated if its limitations are ignored. Proper material selection, edge protection, quality control, and application-specific design are essential to ensure real-world safety rather than relying solely on the “tempered” label.