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A reliable, end-to-end power supply solution for components of a telecommunications network provides either a primary source or a backup source of electrical power at various telecommunications sites for reliable operation of telecommunications equipment. One subsystem of the power supply solution i

A reliable, end-to-end power supply solution for components of a telecommunications network provides either a primary source or a backup source of electrical power at various telecommunications sites for reliable operation of telecommunications equipment. One subsystem of the power supply solution includes one or more proton exchange membrane type fuel cells and an energy storage device for storing DC electrical power produced by the fuel cells. Another subsystem includes one or more microturbine generators, one or more rectifiers for converting AC electrical power produced by the microturbine generators to DC electrical power, and one or more proton exchange membrane type fuel cells for producing DC electrical power. The power supply solution ensures that voice and data traffic is reliably handled by a telecommunications network in situations where commercial electric utilities fail to supply power at certain points along the network.

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1. A method for supplying power to a telecommunications network, the method comprising: providing a primary power source component comprising at least a first proton exchange membrane (PEM), a second parallel PEM, and a reformer for supplying the first and second PEMs with hydrogen fuel, wherein the

1. A method for supplying power to a telecommunications network, the method comprising: providing a primary power source component comprising at least a first proton exchange membrane (PEM), a second parallel PEM, and a reformer for supplying the first and second PEMs with hydrogen fuel, wherein the first PEM generates DC electrical power during a normal operating mode;providing DC electrical power from an energy storage device operable, (1) during, at least a startup phase of power generation of a secondary power source component that includes at least one PEM for generating DC electrical power during a backup mode, or(2) upon a low pressure condition being sensed in an in-line valve of the secondary power source component, wherein the low pressure condition is indicative of an insufficient fuel flow from a set of liquid hydrogen storage tanks that are adapted to directly provide hydrogen fuel to the secondary power source, wherein the set of hydrogen storage tanks are separate from the reformer;once the secondary power source component moves from the startup phase of power generation to a steady state operation during a backup mode, stopping the energy storage device from providing the DC electrical power and providing the DC electrical power from the secondary power source component during the backup mode; andproviding a DC bus for interconnecting, in parallel, at least the primary power source component, the secondary power source component, the energy storage device, and a programmable logic controller (PLC), wherein the PLC manages switching between the secondary power source component and the energy storage device when the low pressure condition is detected for the secondary power source component. 2. The method of claim 1, further comprising: providing DC electrical power from at least one of the primary power source component or the secondary power source component during a first operational phase, andproviding DC electrical power converted from incoming AC electrical power via a rectifier during a second operational phase. 3. The method of claim 2, further comprising providing DC electrical power from the energy storage device operable during at least a portion of the second operational phase. 4. The method of claim 1, further comprising converting incoming AC electrical power to DC electrical power via at least one rectifier during a third operational phase. 5. The method of claim 1, further comprising: providing a second PEM within the primary power source component, wherein the second PEM generates DC electrical power during a normal operating mode,wherein the first PEM is adapted to operate substantially during a first operational phase and to directly receive hydrogen fuel from the hydrogen reformer storage device, andwherein the second PEM is adapted to receive hydrogen fuel via an automated pressure-controlled valve located in-line between the second PEM and the hydrogen reformer. 6. The method of claim 5, further comprising providing telecommunications electronics, wherein the DC bus powers the telecommunications equipment using the DC electrical power delivered to the DC bus from at least one of the primary power source component or the secondary power source component. 7. The method of claim 6, wherein the PLC is operably coupled to the automated pressure-controlled valve, and wherein the PLC is located at a wireless communication site that accommodates a base transceiver system. 8. The method of claim 7, further comprising using the PLC to selectively allow or disallow a flow of the hydrogen fuel to the second PEM by controlling the automated pressure-controlled valve. 9. A method for supplying power to a telecommunications network, the method comprising: providing a primary power source component that includes a first proton exchange membrane (PEM) and a second PEM, a reformer connected to a first fuel source for supplying the first PEM and the second PEM with fuel, wherein the first PEM, the second PEM, or a combination thereof generates DC electrical power during a normal operating mode;providing a secondary power source component that includes at least one PEM for generating DC electrical power during a backup mode, wherein the at least one PEM in the secondary power source is adapted to directly receive fuel from a second fuel source distinct and separate from the first fuel source;providing a programmable logic controller (PLC) that manages switching between the primary power source component and the secondary power source component as a function of whether the primary power source component is capable of producing DC electrical power;providing a DC bus for interconnecting at least the primary power source component and the secondary power source component, and the PLC, in parallel, wherein the DC bus powers the PLC using the DC electrical power delivered to the DC bus from at least one of the primary power source component or the secondary power source component, wherein the PLC is powered with AC electrical power via an inverter; andproviding an in-line automated pressure-control valve installed to a fuel line between the first PEM and the second PEM of the primary power source component, wherein the first PEM and the second PEM are positioned in parallel, wherein the PLC is operably coupled to the automated pressure-controlled valve to selectively supply hydrogen gas to both the first PEM, the second PEM when dictated by a power-consumption load on the DC bus. 10. A method for supplying power to a telecommunications network, the method comprising: providing telecommunications equipment within a site;providing an air cooling system for regulating temperature of the site;providing a primary power source component that includes two or more parallel proton exchange membranes (PEMs) and a hydrogen reformer connected to a first hydrogen fuel source for supplying the one or more PEMs of the primary source component with hydrogen fuel, wherein the one or more PEMs of the primary power source component generate DC electrical power during a normal operating mode;providing a secondary power source component that includes at least one PEM for generating DC electrical power during a backup mode, wherein the at least one PEM in the secondary power source is adapted to directly receive hydrogen fuel from a second hydrogen fuel source distinct and separate from the first hydrogen fuel source;providing a programmable logic controller (PLC) within the site that manages switching between the primary power source component and the secondary power source component as a function of whether the primary power source component is capable of producing DC electrical power, wherein the PLC manages switching between the primary power source component and the secondary power source component when a low pressure condition is sensed in an in-line valve of the primary power source component, wherein the low pressure condition is indicative of an insufficient fuel flow from a set of fuel storage tanks that are adapted to provide hydrogen fuel to the primary power source component; andproviding a DC bus for interconnecting at least the primary power source component and the secondary power source component, in parallel;wherein the DC bus further powers the telecommunications equipment is with DC electrical power and, wherein the DC bus powers the PLC and the air cooling system with AC electrical power via an inverter. 11. The method of claim 10, wherein the PLC is operably coupled to an automated pressure-controlled valve. 12. The method of claim 11, further comprising using the PLC to selectively allow or disallow a flow of the hydrogen fuel to the at least one PEM in the secondary power source by controlling the automated pressure-controlled valve.