A fuel cell system includes: a first fuel cell stack; and a second fuel cell stack with lower output voltage than the first fuel cell stack, a pre-switching stack configured by the first fuel cell stack or the second fuel cell stack, a step-up stack configured by the first fuel cell stack or the second fuel cell stack, a post-switching stack configured by at least the first fuel cell stack, and steps up voltage of the step-up stack with the pre-switching stack connected to the load and then switches to a connection state where the post-switching stack is connected to the load.

A method for operating a fuel cell system includes drawing a base level DC electric energy from a first fuel cell of a first type to a combined DC bus, measuring a DC voltage at the combined DC bus, determining whether the DC voltage at the combined DC bus falls short of a DC voltage threshold, and drawing a variable DC electric energy from a second fuel cell of a second type different from the first type in response to determining that the DC voltage at the combined DC bus falls short of the DC voltage threshold.

A method for operating a fuel cell system includes drawing a base level DC electric energy from a first fuel cell of a first type to a combined DC bus, measuring a DC voltage at the combined DC bus, determining whether the DC voltage at the combined DC bus falls short of a DC voltage threshold, and drawing a variable DC electric energy from a second fuel cell of a second type different from the first type in response to determining that the DC voltage at the combined DC bus falls short of the DC voltage threshold.

Techniques of deploying fuel cells in a facility are described herein. In one embodiment, a method includes identifying a location of the receptacle at the facility that the fuel cell is connected upon detecting the fuel connector of the second side of the carrier being coupled to a fuel port at a receptacle at the facility. The method can then include generating and storing, in a database, a fuel cell record indicating that the fuel cell is physically connected to the receptacle at the identified location in the facility and instructing a control device in the facility corresponding to the identified location to provide fuel to the fuel cell via the fuel port, the fuel connector, the connection between the first side and the second side of the carrier, and the fuel inlet of the fuel cell.

A load-following fuel cell system for a grid system operating with a high penetration of intermittent renewable energy sources includes a baseload power generation module and a load-following power generation module. The baseload power generation module provides a baseload power to the grid system and includes a high-efficiency fuel cell system. The high-efficiency fuel cell system includes a topping module and a bottoming module. The topping module and the bottoming module are connected in series and the topping module provides an exhaust stream to the bottoming module. The load-following power generation module provides a load-following power to the grid system and includes an energy storage system that separates and stores hydrogen contained in the exhaust stream and a power generation system having one or more fuel cells. The power generation system receives the hydrogen from the energy storage system to provide the load-following power.

An energy storage system for an electrical grid running on a renewable energy source includes a baseload power module, a waste converter module, and a load-following power module. The baseload power module includes a first fuel cell system configured to provide a baseload power to the electrical grid. The waste converter module is configured to extract and store hydrogen from an exhaust stream produced by the first fuel cell system. The load-following power module includes a second fuel cell system configured to receive hydrogen from the waste converter module and convert the hydrogen to electrical energy to support the electrical grid.

A vehicle system comprising a fuel cell, at least one container for the storage of ammonia precursor, and a first and second fuel generator. The first and second fuel generators are configured to convert the ammonia precursor into fuel for use in the fuel cell. The first fuel generator is configured to carry out the ammonia precursor conversion within a lower temperature range than the second fuel generator.

A vehicle system comprising a fuel cell, at least one container for the storage of ammonia precursor, and a first and second fuel generator. The first and second fuel generators are configured to convert the ammonia precursor into fuel for use in the fuel cell. The first fuel generator is configured to carry out the ammonia precursor conversion within a lower temperature range than the second fuel generator.

A fuel cell system includes: a first fuel cell stack; and a second fuel cell stack with lower output voltage than the first fuel cell stack, a pre-switching stack configured by the first fuel cell stack or the second fuel cell stack, a step-up stack configured by the first fuel cell stack or the second fuel cell stack, a post-switching stack configured by at least the first fuel cell stack, and steps up voltage of the step-up stack with the pre-switching stack connected to the load and then switches to a connection state where the post-switching stack is connected to the load.

A power generation system includes a first power generation apparatus, a second power generation apparatus, and a controller configured to control at least one of the first power generation apparatus and the second power generation apparatus. The controller supplies heat generated from power generation by one of the power generation apparatuses to the other of the first power generation apparatus and the second power generation apparatus. A control method of the power generation system includes a power generation step in which one of the first power generation apparatus and the second power generation apparatus generates power; a heat generation step of generating heat from power generation by the one of the power generation apparatuses at the power generation step; and a heat supply step of supplying the heat generated at the heat generation step to the other of the first power generation apparatus and the second power generation apparatus.