I found this thread because I have exactly the same model of inverter (Voltronic Axpert MKS 5kVA) which exhibited the same fault condition. I want to say thank you for all the posts here because this helped me to fix my inverter quickly and it didn't cost me anything. I am electronic engineer in South Africa with 30+ years experience in hardware and software design. I have also designed a 1kW switch mode battery charger using active power factor correction. I performed my own solar inverter installation around 5 years ago with the above mentioned Axpert 5kVA. It also has the same printing on it as per @Plaasjapie 's post (TheSunpays.co.za). It suddenly exhibited the same fault. I disassembled and found the two guilty capacitors C78 and C79. It would seem that this is a common failure point on this design. From my analysis of the reason for failure of the components is either because they have insufficient voltage rating or they have insufficient ripple current rating, or both. The capacitors are used for smoothing on the output of what appears to be an auxillary power supply supplying +5V and -12V to the circuit. This can be deduced from that switch mode transformer nearby, the output diodes feeding the capacitors and the 7912 and 78M05 regulators. The 7912 regulator is a standard -12V linear regulator and given the dropout voltage required for it to operate the input voltage would need to be around -14V or lower. The capacitors on my board were 16V rated. This is way too close to the maximum rated working voltage of the capacitors. They should be at least 25V rated or higher. Just to respond to the comment by @Coulomb about operating electrolytics at 80% of rated voltage. That is not quite correct: To begin with the way the maximum rated working voltage of an electrolytic capacitor is determined during testing is they crank up the voltage and measure the rate of spark through events on the dielectric. When the rate of spark through events reaches a certain value that is how they determine the maximum safe working voltage. So in essence at the maximum rated voltage the capacitor is already failing, just very slowly. So it's definitely a good idea to have quite a margin when it comes to working voltage. Also the value tolerance of most electrolytic capacitors is +/-20%. No circuit should be designed using an electrolytic capacitor where an accurate value is required. In this case the electrolytics are used for smoothing so the value chosen should be "enough" to perform adequate smoothing but doesn't need to be an exact value, more is better. The choice of value might also affect the corner frequency of the control loop for the switch mode, but again the design should allow for a wide tolerance of capacitance value. But what is more important is the capacitors should be of the low ESR type (low equivalent series resistance). All capacitors used in switch mode circuits where high frequency ripple currents are involved must be chosen for low loss and have sufficient ripple current ratings for the design. In addition the ripple current rating is reduced at high temperature. Another indicator that the capacitors are handling high frequency ripple currents are the small ceramic chip capacitors solder directly between the pins of the capacitors on the underside of the board. They are there to handle the very high frequencies where the electrolytics impedance starts to climb because of parasitic inductance. But this doesn't mean that they handle the bulk of the high frequency ripple currents. The capacitors I found on my board were 16V rated and appeared to be made by a company called yst. There are no other markings to indicate which series they are. I googled yst and the information is sketchy on the manufacturer. I replaced the capacitors with some Rubycon YXF series 1000uF 35V capacitors I had in my stash and the inverter is working fine now. I just didn't have 25V rated capacitors but it didn't matter. Rubycon is a reputable manufacturer and the YXF series are low ESR 105C rated capacitors with long life. I've used Rubycon YXF for years and they've never failed me. I do not want to have to replace the caps again in 5 years time. You can use any capacitors from a reputable manufacturer that are specifically Low ESR and high temperature rated, such names as Rubycon, Nichicon, Panasonic, TDK Epcos, BHC Aerovox, Wurth etc come to mind. They only cost a little more than standard grade but its worth it. My guess is the yst capacitors used on the board are just standard grade capacitors and with insufficient voltage and ripple current rating, thus the failure and it's clearly happening on a lot of these inverters so it's a design flaw, not a random failure. I hope this explanation helps.