TriplePoint.Threads by TriplePoint.Engineering

In pressure-retaining systems, most welds are validated through hydrostatic testing. But one weld stands apart, the golden joint. It’s not just the last weld in the sequence. It’s the one that closes the system, cannot be pressure-tested, and demands absolute confidence in workmanship and inspection. This article explore s what defines a golden joint, when it’s used, how it’s executed, how it differs from a regular weld, and how European regulations frame its acceptance. What Is a Golden Joint? A golden joint, also known as a golden weld or closure weld, is the final connection in a piping system where hydrostatic testing is no longer feasible. Once completed, the system is sealed. There’s no opportunity to apply internal pressure to validate its integrity. Instead, the weld must be proven sound through non-destructive examination (NDE) alone. Golden joints are not inherently different in geometry or metallurgy from other welds. What sets them apart is context. They are performed...

  EN 50160 and PV Systems Photovoltaic systems are more than solar panels on a roof. They are active participants in a dynamic electrical ecosystem, constantly interacting with the public grid. That interaction is governed by standards, and one of the most important is EN 50160. This European standard defines the expected quality of electricity supplied by public distribution networks. For PV system owners, understanding EN 50160 is essential for protecting equipment, maximizing performance, and ensuring long-term compliance. EN 50160 sets expectations for voltage levels, frequency stability, and how much variation is acceptable. In most homes across Europe, the voltage should remain within ten percent of the nominal 230 volts. Anything above 253 volts is considered too high. Frequency, typically 50 hertz, should stay within one percent of that value for 99.5 percent of the week. These thresholds are designed to protect sensitive electronics, maintain grid stability, and ensure...

In the world of mechanical integrity, precision matters. Few tasks exemplify this more than torquing. It’s easy to overlook, often relegated to a checklist item or a routine step in assembly. But make no mistake, torquing is not optional, and it’s certainly not trivial. It’s the fine line between structural integrity and catastrophic failure. Whether you're tightening bolts on a flange in a chemical processing plant, assembling a wind turbine in the field, or maintaining high-pressure steam lines in a refinery, torquing is about control. It’s about applying the right force, in the right sequence, under the right conditions. And yet, despite its critical importance, I still see teams treating it like a formality rather than a precision engineering task. Let’s break it down. Here’s what truly matters when it comes to torquing—and why it deserves your full attention. Hydraulic torqueing 1. What Is Torquing and Why Do It? Torquing is the controlled tightening of bolts and nuts to achie...