	US 12,435,435 B1
	Systems for generating hydrogen
Mohammed Alshaiba Saleh Ghannam Almazrouei, Abu Dhabi (AE); Sajid Bhatti, Abu Dhabi (AE); and Daniel Charaf Eddine Chehayeb, Abu Dhabi (AE)
Assigned to Shaheen Innovations Holding Limited, Abu Dhabi (AE)
Appl. No. 18/864,415
Filed by SHAHEEN INNOVATIONS HOLDING LIMITED, Abu Dhabi (AE)
PCT Filed May 13, 2024, PCT No. PCT/GB2024/051240 § 371(c)(1), (2) Date Nov. 8, 2024, PCT Pub. No. WO2024/236282, PCT Pub. Date Nov. 21, 2024.
Claims priority of provisional application 63/599,898, filed on Nov. 16, 2023.
Claims priority of provisional application 63/466,201, filed on May 12, 2023.
This patent is subject to a terminal disclaimer.
Int. Cl. C25B 15/023 (2021.01); B06B 1/02 (2006.01); C25B 9/19 (2021.01); C25B 13/08 (2006.01)

CPC C25B 15/023 (2021.01) [B06B 1/0215 (2013.01); C25B 9/19 (2021.01); C25B 13/08 (2013.01); B06B 2201/55 (2013.01)]

16 Claims

1. A system for generating hydrogen gas, the system comprising:

a reaction vessel containing an aqueous solution;

a cathode positioned at least partly within the reaction vessel with a portion of the cathode having an exterior surface submersed in and in electrical contact with the aqueous solution to create an interface for a reduction reaction for reducing H⁺ ions to produce hydrogen gas at the cathode;

an anode positioned at least partly within the reaction vessel with a portion of the anode submersed in and in electrical contact with the aqueous solution to create an interface for an oxidation reaction for oxidizing OH⁻ions to produce oxygen gas at the anode, wherein the cathode and the anode are configured to receive power from a power source;

a polymer-electrolyte membrane (PEM) positioned between the cathode and the anode to segregate the H⁺ ions and the OH⁻ ions in the aqueous solution to create divided areas in the reaction vessel, wherein the aqueous solution in a divided area proximate the cathode has a greater concentration of H⁺ ions than OH⁻ions;

a first ultrasonic transducer positioned at least partly in the reaction vessel in the aqueous solution, the first ultrasonic transducer positioned at a predetermined distance from the cathode and oriented such that the first ultrasonic transducer emits ultrasonic waves at least partly towards the exterior surface of the cathode to agitate the aqueous solution proximate to the exterior surface of the cathode to clear any bubbles of the hydrogen gas formed at the exterior surface of the cathode to expose the exterior surface of the cathode to additional H⁺ ions for generation of hydrogen gas;

a second ultrasonic transducer positioned at least partly in the reaction vessel in the aqueous solution, the second ultrasonic transducer positioned at a predetermined distance from the anode and oriented such that the second ultrasonic transducer emits ultrasonic waves at least partly towards the exterior surface of the anode to cause cavitation in the aqueous solution proximate to the exterior surface of the anode, wherein the cavitation weakens hydrogen bonds between water molecules of the aqueous solution to separate individual water molecules available for interaction with the anode to undergo the oxidation reaction at the anode to oxidize OH⁻ions and form oxygen gas at the anode; and

a plurality of transducer drivers each coupled electrically to a respective one of the first ultrasonic transducer or the second ultrasonic transducer to drive the ultrasonic transducer to generate the ultrasonic waves, wherein each transducer driver comprises:

an H-bridge circuit connected to the ultrasonic transducer, wherein the H-bridge circuit generates an AC drive signal to drive the ultrasonic transducer to generate and transmit the ultrasonic waves;

a microchip connected to the H-bridge circuit to control the H-bridge circuit to generate the AC drive signal, the microchip comprising:

an oscillator which generates:

a main clock signal,

a first phase clock signal which is high for a first time during the positive half-period of the main clock signal and low during the negative half-period of the main clock signal, and

a second phase clock signal which is high for a second time during the negative half-period of the main clock signal and low during the positive half-period of the main clock signal, wherein the phases of the first phase clock signal and the second phase clock signal are centre aligned;

a pulse width modulation (PWM) signal generator subsystem comprising:

a delay locked loop which generates a double frequency clock signal using the first phase clock signal and the second phase clock signal, the double frequency clock signal being double the frequency of the main clock signal, wherein the delay locked loop synchronizes the first phase clock signal and the second phase clock signal, and wherein the delay locked loop adjusts the frequency and the duty cycle of the first phase clock signal and the second phase clock signal in response to a driver control signal to produce a first phase output signal and a second phase output signal, wherein the first phase output signal and the second phase output signal are configured to drive the H-bridge circuit to generate the AC drive signal to drive the ultrasonic transducer;

a first phase output signal terminal which outputs the first phase output signal to the H-bridge circuit;

a second phase output signal terminal which outputs the second phase output signal to the H-bridge circuit;

a feedback input terminal which receives a feedback signal from the H-bridge circuit, the feedback signal being indicative of a parameter of the operation of the H-bridge circuit or the AC drive signal when the H-bridge circuit is driving the ultrasonic transducer with the AC drive signal;

an analogue to digital converter (ADC) subsystem comprising:

a plurality of ADC input terminals which receive analogue signals, wherein one of the ADC input terminals is connected to the feedback input terminal such that the ADC subsystem receives the feedback signal from the H-bridge circuit, and wherein the ADC subsystem samples analogue signals received at the ADC input terminal at a sampling frequency which is proportional to the frequency of the main clock signal and the ADC subsystem generates ADC digital signals using the sampled analogue signal;

a digital processor subsystem which receives the ADC digital signals from the ADC subsystem and processes the ADC digital signals to generate the driver control signal, wherein the digital processor subsystem communicates the driver control signal to the PWM signal generator subsystem to control the PWM signal generator subsystem;

a digital to analogue converter (DAC) subsystem comprising:

a digital to analogue converter (DAC) which converts a digital control signal generated by the digital processor subsystem into an analogue voltage control signal to control a voltage regulator circuit which generates a voltage for modulation by the H-bridge circuit;

a DAC output terminal which outputs the analogue voltage control signal to control the voltage regulator circuit to generate a predetermined voltage for modulation by the H-bridge circuit to drive the ultrasonic transducer to control the cavitation in the aqueous solution in response to feedback signals which are indicative of the operation of the ultrasonic transducer;

a hydrogen gas collector in fluid communication with the reaction vessel to collect hydrogen gas produced within the reaction vessel; and

a hydrogen gas pressure sensor which senses the pressure of hydrogen gas within the hydrogen gas collector and provides a hydrogen gas pressure signal, wherein the hydrogen gas pressure sensor is electrically coupled to a further one of the ADC input terminals of each transducer driver, wherein the ADC subsystem of each transducer driver samples the hydrogen gas pressure signal received at the further one of the ADC input terminals at a sampling frequency which is proportional to the frequency of the main clock signal and the ADC subsystem and generates an ADC digital hydrogen gas pressure signal using the sampled hydrogen gas pressure signal, and wherein the digital processor subsystem of each transducer driver receives the ADC digital hydrogen gas pressure signal from the ADC subsystem and processes the ADC digital hydrogen gas pressure signal to modify the driver control signal in response to a change in the hydrogen gas pressure signal,

wherein each transducer driver manages the efficiency of operation of the system in response to the hydrogen gas pressure signal received at the ADC input terminal of each transducer driver, wherein each of the plurality of transducer drivers controls the frequency and power of the AC drive signal driving a respective one of the ultrasonic transducers to adjust the frequency and intensity of ultrasonic waves emitted by each ultrasonic transducer to control the cavitation in the aqueous solution to control the volume and rate of hydrogen gas generated by the system.