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Full-Bridge Topology Cell Capacitance Verification
The purpose of this test is to determine whether the cell capacitance is correct. To achieve the purpose of test, we can charge the cells with a certain arm current, and then observe if the final Vcap of the cell equals to the mathematic calculation value. So this test can also test whether the cells can be charged at normal work state.
There are 2 kinds of arm currents can be used here to verify the cell capacitance:
- a pulse arm current;
- a sin wave arm current.
Test Based on a Pulse Arm Current
- System initialization.
- Change the Vcap mode to 0: normal operation.
- Give ON signal to the second cell G1 gate signal and give OFF signal to the G3 gate in MMC pulse block (for easy testing).
- Setup the arm current waveform in console. To create a pulse with magnitude of 0.1 and duration of 0.01s, setup the current as initialization.
- Turn on the current switch to create the current pulse. Pay attention to the Vcap observer. If every time the switch turned on and off, the Vcap is added nearly by 0.1, the test result is correct, as shown in Figure 43.
It should be noted that the mathematic calculation of Vcap is below:
Vcap=1/Ccell* integral (iarm) +Vcap_initial
In this test, Ccell=0.01; Iarm is “A pulse with magnitude of 0.1 and duration of 0.01 s” so integral iarm =0.1*0.01=0.001; and Vcap_initial = 0;
So after the pulse, Vcap = 1/0.01*0.001+0=0.1.
Test Based on a Sine Wave Arm Current
- System initialization.
- Set the number of cells per arm wanted to be tested in MMC Parameter block, and change the Sb and Vb correspondingly. For example, here the number of cells per arm is set to 10, Sb and Vb are also set to 10. Set the cell capacitance value to 1/(2*pi*50) for easy testing.
- Change the Vcap mode to 3: Vcap reset to a fixed value, at the same time change the Vcap fixed value to 1. After this operation, the Vcap of each cell should be set to 1, the Total Vcap should be set to 10, and the Vmmc still remain 0.
- Give ON signal to G1 and give OFF signal to G3 of the 2nd cell in MMC pulse block (for easy testing). After this operation, the Vmmc should be changed to 1.
- To generate a sin wave arm current with magnitude 0.1 and frequency of 50 Hz, set up the Arm Current Generation block as Table 7.
- Change the Vcap mode to 0: normal operation. After this operation, the Vcap of the 2nd cell, Vmmc and Total Vcap become sinusoidal (dc component + ac component). For the ac component, the frequency is 50 Hz and magnitude is 0.1.
It should be noted that the mathematic calculation of Vcap is below:
Vcap=1/Ccell* integral (iarm) +Vcap_initial
In this test, Ccell=1/(2*pi*50); Iarm =0.1sin(100*pi*t); so integral iarm =-0.1cos(100*pi*t)/(100*pi); and Vcap_initial = 1;
So after the pulse, Vcap = -0.1cos(100*pi*t)+1=1-0.1cos(100*pi*t).
Cells Discharging Resistor Validation at Normal Work State Test
This test is designed to test whether the cells can be discharged at normal work state or not. This test is the test in section 3.6.
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