Supercapacitors are finding their way into an increasing number of applications for short-term energy storage. One such application is a power ride-through circuit, in which a backup energy source cuts in and powers the load when main power supply fails for a short time. This type of application has been dominated by batteries in the past, but supercapacitors are fast making inroads as their price-per-farad, size and effective series resistance per capacitance (ESR/C) continue to fall.
In a power ride-through application, series-stacked capacitors must be charged and cell-voltage balanced. Supercapacitors are switched into the power path when needed and the power to the load is controlled by a DC/DC converter. Features that make a good choice for power ride-through applications include small package size, programmable charging current, automatic cell voltage balancing, and low drain current on the supercapacitors and a, low noise, constant current charger.
Two parameters of the supercapacitor that are critical to an application are cell voltage and initial leakage current. The manufacturers of supercapacitors rate their leakage current after 100 hours of applied voltage while the initial leakage current in those first 100 hours may be as much as 50 times the specified leakage current.
An alternative is to use a non-dissipative active cell balancing circuit, such as the LTC3225, to maintain cell voltage. The LTC3225 presents less than 4µA of load to the supercapacitor when in shutdown mode and less than 1µA when input power is removed. The LTC3225 features a programmable charging current of up to 150mA, charging two series supercapacitors while balancing the voltage on the capacitors.
Power Ride-through Applications
To estimate the requirements for the supercapacitor, the effective circuit resistance (RT) needs to be determined. RT is the sum of the capacitors’ ESRs and the circuit distribution resistances.
Assuming 10% of the input power is lost in the effective circuit resistance when the DC/DC converter is at VUV, the worst case RT is
The voltage required across the Supercapacitor at VUV threshold of the DC/DC converter is;
The required effective capacitance can then be calculated based on the required ride-through time (TRT), and the initial voltage on the capacitor (VC(0)) and VC(UV).
The ESR of a supercapacitor decreases with higher frequency. Manufacturers usually specify the ESR at 1kHz, while some manufactures publish both the value at DC and at 1kHz. The capacitance of supercapacitors also decreases as frequency increases and is usually specified at DC. When using a supercapacitor in a ride-through application where the power is being sourced for seconds to minutes, use the effective capacitance and ESR measurements at a low frequency, such as 0.3Hz.
Figure 2 shows a 12V power system that uses six 10F, 2.7V supercapacitors in series charged by three LTC3225’s set to 4.8V and a charging current of 150mA. The three LTC3225’s are powered by three floating 5V outputs generated by the LT1737 flyback controller. The output of the stack of six supercapacitors is set up in a diode OR arrangement via the LTC4355 dual ideal diode controller. The LTM4601A µModule DC/DC regulator produces 1.8V at 11A from the OR’d outputs. The LTC4355’s MON1 in this application is set for 10.8V.