Blue Ring Tester Schematic Diagram Exclusive May 2026
A: No. An LC meter measures inductance and capacitance. The Blue Ring Tester measures Q factor and loss—a different parameter.
Introduction: What is a Blue Ring Tester? In the world of electronics repair, few tools inspire as much curiosity—and confusion—as the Blue Ring Tester . For decades, technicians repairing switch-mode power supplies (SMPS), flyback transformers (LOPT), and deflection yokes have struggled with a common problem: How do you test a coil or transformer for shorted turns without expensive equipment?
Enter the Blue Ring Tester. This brilliant, low-cost device uses a pulse ringing test to identify shorted turns instantly. Today, we are providing an along with a component-level explanation of how it works. Exclusive Content Notice: The schematic presented below has been redrawn and refined from original service manuals and reverse-engineered vintage units. It includes component values that are often missing or incorrect in other online sources. Part 1: The Exclusive Blue Ring Tester Schematic Diagram Below is the complete schematic diagram of the classic Blue Ring Tester. This design uses a 555 timer, a comparator (LM393), and a handful of passive components to generate a short ringing pulse and analyze the decay. blue ring tester schematic diagram exclusive
A: Indirectly, yes. If you swap the inductor and capacitor positions, you can test capacitors for high ESR (equivalent series resistance). That's a separate article.
A: We are providing the Gerber files and Eagle CAD files to our newsletter subscribers. [Link to signup – keep this organic] Conclusion: A Timeless Tool for the Smart Technician The Blue Ring Tester is a masterpiece of analog design. With fewer than 20 components, it solves a problem that stumps $10,000 impedance analyzers in certain scenarios. The exclusive schematic diagram we've shared today has been verified against original units and corrected for modern component availability. Introduction: What is a Blue Ring Tester
| Reference | Value | Notes | |-----------|-------|-------| | U1 | NE555 | Timer IC | | U2 | LM393 | Dual comparator (one used) | | D1, D2 | 1N4148 | Fast switching diodes | | D3 | Red LED | Fault indicator | | D4 | Green LED | Pass indicator | | C1 | 100nF | Ceramic disc | | C2 | 10nF | Polyester | | C3 | 100µF / 16V | Electrolytic | | C4 | 10pF | Ceramic (critical) | | R1 | 10kΩ | 1/4W | | R2 | 1kΩ | 1/4W | | R3 | 100Ω | 1/4W | | R4 | 1MΩ | 1/4W | | R5 | 47kΩ | 1/4W | | R6 | 10kΩ | 1/4W | | R7 | 330Ω | 1/4W | | R8 | 220Ω | 1/4W | | RV1 | 10kΩ trimpot | Calibration | | Lx | Coil under test | External connection | | Power | 9V battery (or 9-12V DC) | Regulated recommended |
The coil under test (Lx) and C2 (10nF) form an LC tank. When the pulse ends, the energy stored in the magnetic field of Lx collapses, causing the tank to resonate at its natural frequency: ( f = \frac12\pi\sqrtLC ). Enter the Blue Ring Tester
The ringing signal is AC-coupled via C4 and clamped by D1, D2 to protect the comparator. The LM393 compares the ringing waveform to ground. For a healthy coil, the ringing crosses zero many times. The comparator outputs a series of pulses for each zero-crossing.