Electrolyzer system converter arrangement

1 . A solar-powered electrolyzer system comprising: a first electrolyzer stack electrically coupled in series with a photovoltaic array; a first converter electrically coupled in series with the first electrolyzer stack and electrically coupled in series with the photovoltaic array; a first converter controller configured to control a current gain of the first converter; and a second electrolyzer stack electrically coupled at an output of the first to converter. 2 . The electrolyzer system of claim 1 , the first converter controller further being configured to perform operations comprising: determining that hydrogen production for the electrolyzer system has decreased by more than a hydrogen threshold amount over a first time period; determining that a current at the first electrolyzer stack has increased by more than a first current threshold over the first time period; and increasing the current gain of the first converter. 3 . The electrolyzer system of claim 1 , the first converter controller further being configured to perform operations comprising: determining that hydrogen production for the electrolyzer system has decreased by more than a hydrogen threshold amount over a first time period; determining that a current at the first electrolyzer stack has decreased by more than a second current threshold over the first time period; and decreasing the current gain of the first converter. 4 . The electrolyzer system of claim 1 , the first converter controller being configured to perform operations comprising modifying the current gain of the first converter to maintain a power dissipated by the electrolyzer system below a power threshold. 5 . The electrolyzer system of claim 1 , the first converter controller being configured to perform operations comprising: determining that a power produced by the photovoltaic array is greater than a threshold; and responsive to determining that the power produced by the photovoltaic array is greater than the threshold, reducing the current gain of the first converter. 6 . The electrolyzer system of claim 1 , further comprising an excitation signal generator to generate a reference excitation signal, the first converter controller being configured to perform operations comprising modulating the current gain of the first converter using the reference excitation signal. 7 . The electrolyzer system of claim 1 , further comprising: a second photovoltaic array; a second converter electrically coupled in series with the first electrolyzer stack and in series with the second photovoltaic array, the second electrolyzer stack being electrically coupled at an output of the second converter; and a second converter controller configured to control a current gain of the second converter. 8 . The electrolyzer system of claim 7 , further comprising: a third photovoltaic array; a third converter electrically coupled in series with the first electrolyzer stack and in series with the third photovoltaic array; a third load electrically coupled at an output of the third converter; and a third converter controller configured to control a current gain of the third converter. 9 . A method of operating a solar-powered electrolyzer system, the electrolyzer system comprising a first electrolyzer stack electrically coupled in series with a photovoltaic array; a first converter electrically coupled in series with the first electrolyzer stack and electrically coupled in series with the photovoltaic array; a first converter controller configured to control a current gain of the first converter; and a second electrolyzer stack electrically coupled at an output of the first converter, the method, comprising: determining, by the first converter controller, that hydrogen production for the electrolyzer system has decreased by more than a hydrogen threshold amount over a first time period; determining, by the first converter controller, that a current at the first electrolyzer stack has increased by more than a first current threshold over the first time period; and increasing, by the first converter controller, the current gain of the first converter. 10 . The method of claim 9 , further comprising: determining, by the first converter controller, that hydrogen production for the electrolyzer system has decreased by more than a hydrogen threshold amount over a first time period; determining, by the first converter controller, that a current at the first electrolyzer stack has decreased by more than a second current threshold over the first time period; and decreasing, by the first converter controller, the current gain of the first converter. 11 . The method of claim 9 , further comprising modifying the current gain of the first converter to maintain a power dissipated by the electrolyzer system below a power threshold. 17 . The method of claim 9 , further comprising: determining, by the first converter controller, that a power produced by the photovoltaic array is greater than a threshold; and responsive to determining that the power produced by the photovoltaic array is greater than the threshold, reducing, by the first converter controller, the current gain of the first converter. 13 . The method of claim 9 , further comprising: generating, by an excitation reference signal generate, a reference excitation signal; and modulating, by the first converter controller, the current gain of the first converter using the reference excitation signal. 14 . The method of claim 9 , further comprising controlling, by a second converter controller, a current gain of a second converter electrically coupled in series with the first electrolyzer stack and in series with a second photovoltaic array, the second electrolyzer stack being electrically coupled at an output of the second converter. 15 . The method of claim 14 , further comprising controlling, by a third converter controller, a current gain of a third converter, the third converter electrically coupled in series with the first electrolyzer stack and in series with a third photovoltaic array, a third load being electrically coupled at an output of the third converter. 16 . A solar-powered electrolyzer system comprising: a first electrolyzer stack electrically coupled in series with a photovoltaic array; a first converter electrically coupled in series with the first electrolyzer stack and electrically coupled in series with the photovoltaic array; a second electrolyzer stack electrically coupled at an output of the first converter; and means for controlling a current gain of the first converter. 17 . The electrolyzer system of claim 16 , further comprising: means for determining that hydrogen production for the electrolyzer system has decreased by more than a hydrogen threshold amount over a first time period; means for determining that a current at the first electrolyzer stack has increased by more than a first current threshold over the first time period; and means for increasing the current gain of the first converter. 18 . The electrolyzer system of claim 16 , further comprising: means for determining that hydrogen production for the electrolyzer system has decreased by more than a hydrogen threshold amount over a first time period; means for determining that a current at the first electrolyzer stack has decreased by more than a second current threshold over the first time period; and means for decreasing the current gain of the first converter. 19 . The electrolyzer system of claim 16 , further comprisi