Ilkkka said:I was looking for that picture (or one like it), but kept getting interrupted by other things at my office. Basically, you connect the positive on the bridge to the positive on the solar controller, and, if you were to use it as a bridge, the bridge negative to the controller negative. The other two (AC input) are the input from the panels, and since it's a bridge, either polarity would work. But if you connect the panel negatives directly to the controller as suggested, instead of through the bridge, (a possibility I didn't think of when I commented earlier), then the problem I had mentioned of adding an extra diode voltage drop (by using a bridge as a bridge) does not occur. In that case the positive from the panel can go to either of the AC inputs, while the negative from the panel remains attached directly to the negative on the solar controller.Thank you! Didn't even cross my mind running all panels through a single rectifier.
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I was looking for that picture (or one like it), but kept getting interrupted by other things at my office. Basically, you connect the positive on the bridge to the positive on the solar controller, and, if you were to use it as a bridge, the bridge negative to the controller negative. The other two (AC input) are the input from the panels, and since it's a bridge, either polarity would work. But if you connect the panel negatives directly to the controller as suggested, instead of through the bridge, (a possibility I didn't think of when I commented earlier), then the problem I had mentioned of adding an extra diode voltage drop (by using a bridge as a bridge) does not occur. In that case the positive from the panel can go to either of the AC inputs, while the negative from the panel remains attached directly to the negative on the solar controller.One nice thing about using a bridge is that if you burn out a diode, you can reverse the polarity to the input and use the other diode.
Power conversion schemes can be straightforward, such as with a set of diodes and a smoothing capacitor, or involving complex integrated circuits with multiple power conversion and regulation stages. However, one component can participate in all these areas and other important applications like radio frequency tuning and ESD protection: the Schottky barrier rectifier. These provide many important functions in electronics thanks to their internal structure and, of course, the Schottky effect.
If you need a diode for rectification that admits current with low forward voltage and fast switching speed, then a Schottky diode is the standard option. These characteristics make Schottky barrier rectifiers useful in power delivery to wave shaping applications. In this article, well look at how these components stack up to their p-n diode cousins and when you might best be served using a Schottky barrier rectifier instead.
In the most basic sense, a Schottky barrier rectifier (or simply Schottky diode) operates in the same manner as a typical semiconductor diode made from Si or Ge. However, its primary purpose is to provide rectification, i.e., allow current to flow only easily along one specific direction. In this way, they are used in typical DC circuits to enable or block current or in AC circuits as part of wave shaping.
The major differences between a Schottky diode include their forward operating characteristics and, most importantly, their structure. Schottky diodes are constructed by depositing a metal electrical contact on a semiconductor; although n-type or p-type materials can be used in Schottky diodes, n-type materials are normally preferred. The reason is that p-type semiconductor Schottky diodes will have lower forward voltage and thus larger reverse bias breakdown current; using an n-type material provides the best balance between forward voltage and reverse bias current. On the other ends of the component, Ohmic contacts are placed to provide non-rectifying connections to the semiconductor.
Schottky barrier rectifier structure.
Compared to p-n junction diodes, Schottky barrier rectifiers have some advantages that make them more useful in switching, high-frequency rectification, and wave shaping applications. Some of the main advantages of Schottky diodes include:
As shown below, the electrical advantages can be seen when comparing IV curves for a Si p-n diode and a Schottky diode. From here, we can see that the larger reverse bias current behavior leads to slower roll-off into the breakdown region, rather than fast avalanche behavior seen in a p-n diode.
IV curves (left) and forward voltage behavior (right) for Si p-n diodes and Schottky diodes.
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The three major application areas for Schottky barrier rectifiers include switching converters for power regulation, ESD protection, and in microwave circuits. Both applications place requirements on three specifications: the junction capacitance (determines the recovery time and frequency response), voltage limit, and current limit.
In power systems, Schottky diodes are switched between forward bias and reverse bias in order to direct a DC current across an inductor and to the output of a regulator circuit. The diode needs to switch and fully modulate between the two states at the same rate as the driving PWM signal in the upstream switching power MOSFETs, which requires low junction capacitance. The other two important specifications are the voltage and current limits; the device should be able to provide rectification at the applied voltage during operation without entering breakdown.
Schottky diodes can be used in microwave circuits that operate up to GHz frequencies in low-load conditions. The recovery time will be limited by the load impedance and the junction capacitance (see below for an example in a 1N Schottky diode). One big advantage of a Schottky diode in microwave circuits compared to a Si p-n diode is its linearity near zero bias, allowing oscillating signals to be collected directly, and without DC offset if needed.
Example junction capacitance in reverse bias for the Vishay 1N-E3/54.
Certain low-voltage or slower transient events can be reliably protected against with Schottky diodes. An example is shown in the circuit diagram below. In this example, two Schottky diodes are placed as pull-up elements to a power rail in reverse bias. The low voltage drop of these diodes enables clamping of moderate currents in reverse bias back to ground from moderately strong ESD events. A very similar application is used in motor control or when driving large inductive loads; placing the Schottky diode parallel around the load in reverse bias will create the same effect and will protect the driver circuit from damage should a back EMF surge event occur. Should very high levels of ESD protection be needed, a good option is something like a gas discharge tube.
ESD protection with Schottky diodes.
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