Powder conditioner with reduced capacitor voltage ripples

What is claimed is: 1. A power conditioner used to control power flow between a first microgrid and a second microgrid, each of the first and second microgrids having a neutral terminal, said power conditioner comprising: a power converter module used to be coupled to the first microgrid for receiving a three-phase AC (alternating current) power input therefrom, used to be coupled further to the second microgrid, further receiving a PWM (pulse width modulation) output, and including two capacitors that are coupled to each other, a common node of said capacitors being used to be coupled to the neutral terminal of the first microgrid, and being used to be coupled further to the neutral terminal of the second microgrid for receiving a first zero sequence current input therefrom, said power converter module performing AC to DC (direct current) to AC conversion upon the three-phase AC power input based on the PWM output to generate a DC voltage across said capacitors, and to generate a three-phase AC power output for the second microgrid; a detector module coupled to said power converter module, detecting voltages and current inputs of the three-phase AC power input to generate a first detection output, and further detecting the first zero sequence current input to generate a second detection output; and a control module coupled to said detector module for receiving the first and second detection outputs therefrom, and coupled further to said power converter module, said control module generating the PWM output for said power converter module based at least on the first and second detection outputs, such that said common node of said capacitors further receives, from the neutral terminal of the first microgrid, a second zero sequence current input which has a non-zero amplitude and is anti-phase with the first zero sequence current input when the first zero sequence current input has a non-zero amplitude. 2. The power conditioner of claim 1 , wherein: said detector module further detects the DC voltage to generate a third detection output; and said control module further receives the third detection output from said detector module, further receives a target voltage value, and generates the PWM output based further on the third detection output and the target voltage value such that the DC voltage is stabilized at the target voltage value. 3. The power conditioner of claim 2 , wherein said control module includes: a first control circuit coupled to said detector module for receiving the first to third detection outputs therefrom, further receiving the target voltage value, and generating a first control output based at least on the first to third detection outputs and the target voltage value; and a PWM circuit coupled to said first control circuit for receiving the first control output therefrom, coupled further to said power converter module, and generating the PWM output for said power converter module based at least on the first control output. 4. The power conditioner of claim 3 , each of the voltages and the current inputs of the three-phase AC power input including a positive sequence component, a negative sequence component and a zero sequence component, wherein said first control circuit includes: a command generator coupled to said detector module for receiving the first and third detection outputs therefrom, and further receiving the target voltage value, said command generator generating, based on the first and third detection outputs and the target voltage value, a first control command that is associated with the positive and negative sequence components of the voltages and the current inputs of the three-phase AC power input, said command generator further generating, based on the first detection output, a zero axis voltage value that is associated with the zero sequence components of the voltages of the three-phase AC power input, and a zero axis current value that is associated with the zero sequence components of the current inputs of the three-phase AC power input; a target generator coupled to said detector module for receiving the second detection output therefrom, and generating a target current value based at least on the third detection output; a first calculator coupled to said command generator and said target generator for receiving the zero axis current value and the target current value respectively therefrom, and calculating a difference between the zero axis current value and the target current value to generate a difference current value; a proportional resonator coupled to said first calculator for receiving the difference current value therefrom, and generating a first voltage value based on the difference current value; a second calculator coupled to said command generator and said proportional resonator for receiving the zero axis voltage value and the first voltage value respectively therefrom, and calculating a second voltage value based on the zero axis voltage value and the first voltage value; a first frame transformer coupled to said second calculator for receiving the second voltage value therefrom, and performing synchronous frame to stationary frame transformation upon the second voltage value to generate a second control command; and a third calculator coupled to said command generator and said first frame transformer for receiving the first and second control commands respectively therefrom, coupled further to said PWM circuit, and calculating a sum of the first and second control commands to generate the first control output for said PWM circuit. 5. The power conditioner of claim 4 , wherein the target current value is obtained according to the following equation: I*=−k×i 0 , where I * denotes the target current value, k denotes a compensation factor, and i 0 denotes the first zero sequence current input indicated by the second detection output. 6. The power conditioner of claim 5 , wherein: said detector module further detects voltages respectively across said capacitors to generate a fourth detection output; said target generator further receives the fourth detection output from said detector module, and generates the target current value based further on the fourth detection output and a predetermined threshold voltage value. 7. The power conditioner of claim 6 , wherein: when a minimum of the voltages respectively across said capacitors as indicated by the fourth detection output is determined to be greater than the predetermined threshold voltage value, the compensation factor is set to a predetermined constant that is greater than zero and that is less than or equal to one. 8. The power conditioner of claim 6 , wherein: when a minimum of the voltages respectively across said capacitors as indicated by the fourth detection output is determined to be not greater than the predetermined threshold voltage value, the compensation factor is obtained according to the following equation: k = 2 × ( V p - V 1 , m