Abstract: A method for achieving high output efficiency from an electrolysis system (100) using a plurality of electrolysis cells all located within a single electrolysis tank (101) is provided. Each individual electrolysis cell includes a membrane (105-107), a plurality of low voltage electrodes comprised of at least a first and second anode (117/118; 125/126) and at least a first and second cathode (121/122; 129/130), and a plurality of high voltage electrodes comprised of at least an anode (119; 127) and a cathode (123; 131). Within each cell, the high voltage anode is interposed between the first and second low voltage anodes and the high voltage cathode is interposed between the first and second low voltage cathodes. The low voltage applied to the low voltage electrodes and the high voltage applied to the high voltage electrodes is pulsed with the pulses occurring simultaneously.

Abstract: A power generating system (100) and a method of operating the same is provided, the system utilizing an electrolytic heating subsystem (103). The electrolytic heating subsystem is a pulsed electrolysis system that heats a working fluied contained within a circulation conduit (107) in thermal communication with an electrolysis tank (109) of the electrolytic heating subsystem (103). As the working fluid is circulated through the circulation conduit, it is heated to a temperature above its boiling point, causing at least a portion of the working fluid to be converted to vapor (e.g., steam). The vapor is then circulated through a steam turbine (111), causing its rotation and, in turn, an electric generator (113) coupled to the steam turbine.

Abstract: A power generating system (100) and a method of operating the same is provided, the system utilizing an electrolytic heating subsystem (103). The electrolytic heating subsystem is a pulsed electrolysis system that heats a heat transfer medium contained within a first conduit (109) in thermal communication with the electrolytic heating subsystem and at least one heat exchanger (105). A second conduit (117) coupled to the at least one heat exchanger contains a working fluid. As the working fluid is circulated through the second conduit and through the heat exchanger(s), it is heated to a temperature above its boiling point, causing at least a portion of the working fluid to be converted to vapor (e.g., steam). The vapor is circulated through a steam turbine (119), causing its rotation and, in turn, an electric generator (121) coupled to the steam turbine.

Abstract: A method and apparatus for achieving high output efficiency from an electrolysis system (100) using a plurality of electrolysis cells all located within a single electrolysis tank (101) is provided. Each individual electrolysis cell includes a membrane (105A) and at least one pair of low voltage electrodes of different polarity (115A/116A). The electrolysis system also includes at least one pair of high voltage electrodes (119A/120A). In at least one embodiment, the low voltage electrodes within each electrolysis cell are comprised of at least one pair of low voltage electrodes of a first type (115A/116A) and at least one pair of low voltage electrodes of a second type (117A/118A). In at least one other embodiment, the low voltage electrodes within each electrolysis cell are comprised of at least one pair of low voltage electrodes (701A/702A). The voltage applied to the electrodes is pulsed.

Abstract: An electrolysis system (100) and method of using same is provided. In addition to an electrolysis tank (101) and a membrane (105) separating the tank into two regions, the system includes at least one pair of low voltage electrodes (115/116) of a first type, at least one pair of low voltage electrodes (117/118) of a second type, and at least one pair of high voltage electrodes (121/122). The low voltage applied to the low voltage electrodes (115/116/117/118) and the high voltage applied to the high voltage electrodes (121/122) is pulsed with the pulses occurring simultaneously with the same pulse duration. Low voltage is also applied to the low voltage electrodes (115/116/117/118) during part, or all, of the period of each cycle occurring between pulses.

Abstract: An electrolysis system (100) is provided. In addition to an electrolysis tank (101) and a membrane (105) separating the tank into two regions, the system includes at least one pair of low voltage electrodes (115/117) of a first type comprised of a first material, at least one pair of low voltage electrodes (117/118) of a second type comprised of a second material different from the first material, and at least one pair of high voltage electrodes (121/122) comprised of a material that may be the same as either the first or second material or different from both the first and second material. The low voltage applied to the low voltage electrodes and the high voltage applied to the high voltage electrodes is pulsed with the pulses occurring simultaneously with the same pulse duration.

Abstract: A method of operating an electrolysis system (100) to achieve high hydrogen output flow rates is provided. At least three types of electrodes are positioned within an electrolysis tank (101), the three types including at least one pair of low voltage electrodes (115/117) comprised of a first material, at least one pair of low voltage electrodes (117/118) comprised of a second material different from the first material, and at least one pair of high voltage electrodes (121/122). The low voltage and high voltage cathode electrodes are positioned within one region of the tank (101) while the low voltage and high voltage anode electrodes are positioned within the second region of the tank (101), the two regions separated by a membrane (105). The tank (101) is filled with an electrolyte containing water (103). The power supplied to the low and high voltage electrodes is simultaneously pulsed.

Abstract: A power generating system (100) and a method of operating the same is provided, the system utilizing an electrolytic heating subsystem (103). The electrolytic heating subsystem is a pulsed electrolysis system that heats a working fluid contained within a circulation conduit (107) in thermal communication with an electrolysis tank (109) of the electrolytic heating subsystem (103). As the working fluid is circulated through the circulation conduit, it is heated to a temperature above its boiling point, causing at least a portion of the working fluid to be converted to vapor (e.g., steam). The vapor is then circulated through a steam turbine (111), causing its rotation and, in turn, an electric generator (113) coupled to the steam turbine.

Abstract: A power generating system (100) and a method of operating the same is provided, the system utilizing an electrolytic heating subsystem (103). The electrolytic heating subsystem is a pulsed electrolysis system that heats a heat transfer medium contained within a first conduit (109) in thermal communication with the electrolytic heating subsystem and at least one heat exchanger (105). A second conduit (117) coupled to the at least one heat exchanger contains a working fluid. As the working fluid is circulated through the second conduit and through the heat exchanger(s), it is heated to a temperature above its boiling point, causing at least a portion of the working fluid to be converted to vapor (e.g., steam). The vapor is circulated through a steam turbine (119), causing its rotation and, in turn, an electric generator (121) coupled to the steam turbine.

Abstract: An electrolysis system (100) and method of using same is provided. In addition to an electrolysis tank (101) and a membrane (105) separating the tank into two regions, the system includes at least one pair of low voltage electrodes (115/116) of a first type, at least one pair of low voltage electrodes (117/118) of a second type, and at least one pair of high voltage electrodes (121/122). The low voltage applied to the low voltage electrodes (115/116/117/118) and the high voltage applied to the high voltage electrodes (121/122) is pulsed with the pulses occurring simultaneously with the same pulse duration. Low voltage is also applied to the low voltage electrodes (115/116/117/118) during part, or all, of the period of each cycle occurring between pulses.

Abstract: A method and apparatus for achieving high output efficiency from an electrolysis system (100) using a plurality of electrolysis cells all located within a single electrolysis tank (101) is provided. Each individual electrolysis cell includes a membrane (105-107), a plurality of metal members comprised of at least a first and second metal member (117/118; 125/126) and at least a third and fourth metal member (121/122; 129/130), and a plurality of high voltage electrodes comprised of at least an anode (119; 127) and a cathode (123; 131). Within each cell, the high voltage anode is interposed between the first and second metal members and the high voltage cathode is interposed between the third and fourth metal members. The high voltage applied to the high voltage electrodes is pulsed.

Abstract: A method and apparatus for achieving high output efficiency from an electrolysis system (100) using a plurality of electrolysis cells all located within a single electrolysis tank (101) is provided. Each individual electrolysis cell includes a membrane (105A) and at least one pair of low voltage electrodes of different polarity (115A/116A). The electrolysis system also includes at least one pair of high voltage electrodes (119A/120A). In at least one embodiment, the low voltage electrodes within each electrolysis cell are comprised of at least one pair of low voltage electrodes of a first type (115A/116A) and at least one pair of low voltage electrodes of a second type (117A/118A). In at least one other embodiment, the low voltage electrodes within each electrolysis cell are comprised of at least one pair of low voltage electrodes (701A/702A). The voltage applied to the electrodes is pulsed.

Abstract: A method and apparatus for achieving high output efficiency from an electrolysis system (100) using a plurality of electrolysis cells all located within a single electrolysis tank (101) is provided. Each individual electrolysis cell includes a membrane (105-107), a plurality of low voltage electrodes comprised of at least a first and second anode (117/118; 125/126) and at least a first and second cathode (121/122; 129/130), and a plurality of high voltage electrodes comprised of at least an anode (119; 127) and a cathode (123; 131). Within each cell, the high voltage anode is interposed between the first and second low voltage anodes and the high voltage cathode is interposed between the first and second low voltage cathodes. The low voltage applied to the low voltage electrodes and the high voltage applied to the high voltage electrodes is pulsed with the pulses occurring simultaneously.

Abstract: An electrolysis system (100) and method of using same is provided. In addition to an electrolysis tank (101) and a membrane (105) separating the tank into two regions, the system includes a plurality of metal members comprised of at least a first and a second metal member (121/123) contained within the first tank region and at least a third and a fourth metal member (125/127) contained within the second tank region. The system also includes a plurality of high voltage electrodes comprised of at least an anode (117) interposed between the first and second metal members and at least a cathode (115) interposed between the third and fourth metal members. The high voltage applied to the plurality of high voltage electrodes is pulsed.

Abstract: A method of operating an electrolysis system (100) to achieve high hydrogen output flow rates is provided. At least three types of electrodes are positioned within an electrolysis tank (101), the three types including at least one pair of low voltage electrodes (115/117) comprised of a first material, at least one pair of low voltage electrodes (117/118) comprised of a second material different from the first material, and at least one pair of high voltage electrodes (121/122). The low voltage and high voltage cathode electrodes are positioned within one region of the tank (101) while the low voltage and high voltage anode electrodes are positioned within the second region of the tank (101), the two regions separated by a membrane (105). The tank (101) is filled with an electrolyte containing water (103). The power supplied to the low and high voltage electrodes is simultaneously pulsed.

Abstract: An electrolysis system (100) is provided. In addition to an electrolysis tank (101) and a membrane (105) separating the tank into two regions, the system includes at least one pair of low voltage electrodes (115/117) of a first type comprised of a first material, at least one pair of low voltage electrodes (117/118) of a second type comprised of a second material different from the first material, and at least one pair of high voltage electrodes (121/122) comprised of a material that may be the same as either the first or second material or different from both the first and second material. The low voltage applied to the low voltage electrodes and the high voltage applied to the high voltage electrodes is pulsed with the pulses occurring simultaneously with the same pulse duration.