Commercial Power Supplies

The ATX - PC Supply

Using PC ATX Power Supplies for Stanley Meyer's Technology

PC ATX power supplies are versatile and reliable sources of power, making them well-suited for use in various experimental setups, including those inspired by Stanley Meyer's technology. These power supplies offer multiple regulated voltage taps, flexibility for different AC input levels, and robust current capacity, making them a convenient option for powering different components of a water fuel cell system or other similar applications.

Overview of ATX Power Supplies

ATX power supplies are typically used to provide power to desktop computers, but their capabilities extend beyond computing. A standard ATX power supply is designed to output multiple regulated voltages, usually including 3.3V, 5V, 12V, -5V, and -12V. This range of voltages can support a wide variety of electronics, making it a great choice for DIY projects. Most ATX power supplies can operate from either 120V or 240V AC mains, providing flexibility for international use.

Voltage Taps and Current Capacities

A typical 300W ATX power supply is capable of providing sufficient power for most DIY applications:

Advantages for Stanley Meyer's Applications

One of the primary benefits of using an ATX power supply for Stanley Meyer-inspired work is the convenience of having multiple regulated voltages in one unit. The +5V and +12V rails are particularly useful for powering different stages of Meyer's water fuel cell circuit, including control electronics, pulse-generating circuits, and power switching elements.

Furthermore, ATX power supplies are designed to handle varying AC input voltages, making them adaptable to both 120V and 240V mains. This flexibility is particularly advantageous if you need a portable setup that can be used in different regions. The inclusion of overcurrent and overvoltage protection also ensures the safety of both the components and the operator, making ATX power supplies a reliable choice for experimental work.

Practical Considerations

While ATX power supplies offer many advantages, there are some practical considerations to keep in mind. Firstly, ATX power supplies need a load to operate correctly. Many ATX supplies will not turn on unless they sense a minimum load on one or more of the rails, typically the 5V rail. Adding a power resistor as a dummy load can help ensure stable operation.

Another consideration is the need to properly start the power supply. ATX power supplies are designed to be turned on and off via a signal from the motherboard. To use an ATX power supply independently, you'll need to short the PS_ON pin (usually green) to a ground pin, which will enable the power supply to turn on.

To make using an ATX power supply even more convenient, you can use an ATX breakout board such as the GeeekPi ATX Breakout Adapter Board. This breakout board provides screw terminal connectors for each voltage rail, making it easy to connect to your components without needing to modify the original ATX wiring. The breakout board can be mounted inside a project box, and external switches can be added to control the power supply. This setup allows for a clean and organized power distribution system, complete with easy on/off control for different experimental stages.

Conclusion

PC ATX power supplies are well-suited for projects involving Stanley Meyer's technology due to their regulated voltage outputs, current capacities, and flexibility in AC input voltage. The +5V and +12V rails provide ample current for various experimental components, while the negative voltage rails offer versatility for small-signal applications. By leveraging the features of an ATX power supply, hobbyists and researchers can create efficient, reliable setups to explore water fuel cell technologies and other innovative energy systems.

If you're planning to incorporate an ATX power supply into your own experimental work, make sure to account for proper load requirements and activation procedures to ensure consistent and safe performance.

 

Buck and Boost Converters

Understanding Floating Grounds and Their Impact on Circuitry 

Buck and boost converters are fundamental building blocks in modern electronics, particularly when it comes to managing different voltage levels in DIY projects or experimental setups like those inspired by Stanley Meyer's work. These converters are used to step down (buck) or step up (boost) voltage levels, enabling precise power control for various components. In this article, we'll explore the roles of buck and boost converters, discuss the concept of floating grounds, and examine their impact on circuit design.

Buck Converters

A buck converter is a type of DC-DC converter that steps down voltage from a higher input level to a lower output level. It works by rapidly switching the input voltage on and off using a high-speed transistor, typically a MOSFET, and then filtering the resulting waveform with an inductor and capacitor. This method allows for efficient power conversion with minimal energy losses, making buck converters highly suitable for providing regulated lower voltage to control circuits or microcontrollers in projects.

For example, if you have a +12V rail from an ATX power supply and need to power a microcontroller that requires 5V, a buck converter is an ideal solution. It provides stable voltage with high efficiency, preventing excessive heat generation and ensuring your sensitive components are adequately protected.

Boost Converters

A boost converter, on the other hand, steps up a lower input voltage to a higher output voltage. This type of converter is useful when you need a higher voltage than is available from your power source. Boost converters also use rapid switching, along with inductors and capacitors, to efficiently raise the voltage level.

For applications inspired by Stanley Meyer's technology, a boost converter could be used to step up the 5V or 12V output from an ATX power supply to higher voltage levels needed for driving transformer coils or achieving resonance conditions. By using a boost converter, you can ensure the required voltage is consistently supplied, which is crucial for experiments involving water fuel cells and resonance circuits.

Floating Grounds and Their Impact on Circuitry

Floating grounds refer to situations in which a section of a circuit does not share a common ground reference with the rest of the system. In other words, the ground potential in one part of the circuit is not directly connected to the ground in another part. This can lead to significant challenges, especially when dealing with multiple voltage levels or converters.

In circuits involving buck and boost converters, floating grounds can impact the way current flows through different parts of the system. For instance, when a boost converter is used to step up the voltage, the output voltage is typically referenced to a different potential than the input voltage. If proper grounding is not maintained, floating grounds can cause erratic behavior, such as unexpected voltage offsets, oscillations, or even damage to components.

To prevent issues arising from floating grounds, it's essential to design the circuit with careful consideration of grounding paths. One effective approach is to tie all grounds together at a single point—often referred to as a star ground. This configuration ensures that all parts of the circuit share a common reference point, minimizing potential differences that can lead to floating ground problems.

In some cases, intentionally creating floating grounds can be advantageous. For example, isolating different parts of a circuit can help prevent noise or interference from affecting sensitive components. In such cases, optocouplers or transformers are often used to transfer signals across isolated grounds without creating a direct electrical connection.

Practical Considerations for Buck, Boost, and Grounding in Stanley Meyer's Applications

When using buck and boost converters in Stanley Meyer-inspired projects, it is crucial to understand the requirements of each circuit stage. The +5V and +12V outputs from an ATX power supply can be adapted to meet specific needs using buck or boost converters. However, ensuring a stable ground reference throughout the system is key to achieving reliable and consistent results.

For instance, if you are powering a resonance circuit and control electronics from the same power supply, it's important to manage grounding carefully to avoid interference. A floating ground between the high-voltage resonance circuit and the low-voltage control electronics can lead to signal corruption or improper triggering of components. Using a common ground reference and filtering techniques can help maintain stability.

Conclusion

Buck and boost converters provide a versatile means of managing voltage levels in experimental projects, especially those involving Stanley Meyer's technologies. Whether stepping down voltage with a buck converter or stepping up voltage with a boost converter, these components allow for precise control and efficient power management. However, understanding the concept of floating grounds and their impact on circuitry is crucial to ensure stable and reliable operation.

By taking appropriate measures to manage grounding—whether by tying grounds together or isolating sensitive components—you can prevent many common issues and ensure that your experimental setups operate as intended. Proper use of buck and boost converters, along with careful attention to grounding, will help you achieve consistent and efficient results in your projects.