Systems and methods for storing energy for use by an electric vehicle are disclosed. Systems can include an electric vehicle battery pack including a rack configured to couple a plurality of independently removable battery strings to the vehicle, the battery strings configured to be selectively coupled in parallel to a vehicle power bus. The battery strings may include a housing, a plurality of electrochemical cells disposed within the housing, a circuit for electrically connecting the electrochemical cells, a positive high-voltage connector, a negative high-voltage connector, a switch within the housing, and a string control unit configured to control the switch. Each battery string can include a coolant inlet and a coolant outlet configured to couple with and sealingly uncouple from an external coolant supply conduit and an external coolant return conduit, and an auxiliary connector configured to couple with an external communications system and/or an external low-voltage power supply.

A computer implemented method for managing charge availability of a charge unit (CU) to obtain charge for a battery of an electric vehicle (EV) is provided. The CU includes a computer for processing at least part of the method and for communicating with a server over a network. The method includes receiving, by the server, status information from the computer of the CU. The method includes sending to the computer of the CU instructions to make a reservation for the CU. The reservation is for a user account that has requested a desire to charge the battery of the electric vehicle of the user at the CU or another CU. The method includes sending, by the server, a confirmation for the reservation to the user account. The confirmation is viewable via a device having access to the server via the user account. The method includes sending, by the server, a data regarding a time of availability of the CU to the user account for the reservation. The computer of the CU is configured to display a visual indicator regarding the reservation of the CU.

A computer implemented method for managing charge availability of a charge unit (CU) to obtain charge for a battery of an electric vehicle (EV) is provided. The CU includes a computer for processing at least part of the method and for communicating with a server over a network. The method includes receiving, by the server, status information from the computer of the CU. The method includes sending to the computer of the CU instructions to make a reservation for the CU. The reservation is for a user account that has requested a desire to charge the battery of the electric vehicle of the user at the CU or another CU. The method includes sending, by the server, a confirmation for the reservation to the user account. The confirmation is viewable via a device having access to the server via the user account. The method includes sending, by the server, a data regarding a time of availability of the CU to the user account for the reservation. The computer of the CU is configured to display a visual indicator regarding the reservation of the CU.

A charging system for an autonomous rover includes a charging interface with contacts that interface with the autonomous rover, a rover power source for the autonomous rover, and circuitry operated by the autonomous rover for controlling charging of the rover power source.

A charging system for an autonomous rover includes a charging interface with contacts that interface with the autonomous rover, a rover power source for the autonomous rover, and circuitry operated by the autonomous rover for controlling charging of the rover power source.

Disclosed is a Zero Emission Onboard Charging System that charges the main battery of an electric vehicle when the vehicle is being driven in full operation or is at rest. The Zero Emission Onboard Charging System includes at least one direct current (DC) belt driven generator, at least one wheel, at least one pulley attached to the at least one wheel and configured to be attached by belts to the at least one DC belt driven generator, the at least one DC belt driven generator being configured to be driven by the belts attached to the at least one pulley while the electric vehicle is being driven, a voltage regulator wired to the at least one DC belt driven generator, the voltage regulator being configured to regulate DC power received from the at least one DC belt driven generator and to output a grid-equivalent alternating current (AC) charge output, a charging box wired to the voltage regulator, the charging box being configured to receive the charge output from the voltage regulator, a charge cable having two ends configured with a plug, wherein a first end is plugged into the charging box, and wherein the charge cable is configured to receive the charge output from the charging box, a charge port connected to the charge cable by a second end of the charge cable being plugged into the charge port, the charge port being configured to receive the charge output through the charge cable, and a main battery wired to the charge port, the main battery being configured to receive the charge output from the charge port while the electric vehicle is being driven.

Disclosed is a Zero Emission Onboard Charging System that charges the main battery of an electric vehicle when the vehicle is being driven in full operation or is at rest. The Zero Emission Onboard Charging System includes at least one direct current (DC) belt driven generator, at least one wheel, at least one pulley attached to the at least one wheel and configured to be attached by belts to the at least one DC belt driven generator, the at least one DC belt driven generator being configured to be driven by the belts attached to the at least one pulley while the electric vehicle is being driven, a voltage regulator wired to the at least one DC belt driven generator, the voltage regulator being configured to regulate DC power received from the at least one DC belt driven generator and to output a grid-equivalent alternating current (AC) charge output, a charging box wired to the voltage regulator, the charging box being configured to receive the charge output from the voltage regulator, a charge cable having two ends configured with a plug, wherein a first end is plugged into the charging box, and wherein the charge cable is configured to receive the charge output from the charging box, a charge port connected to the charge cable by a second end of the charge cable being plugged into the charge port, the charge port being configured to receive the charge output through the charge cable, and a main battery wired to the charge port, the main battery being configured to receive the charge output from the charge port while the electric vehicle is being driven.

A charging station includes an alternating current (AC) electrical power input and at least one direct current (DC) electrical power module coupled to the AC electrical power input. The charging station also includes at least one station output having a vehicle DC electrical power output, a communications output, and a dispenser DC electrical power output, the dispenser DC electrical power output being configured to be coupled to at least one dispenser. The charging station further includes a communications hub including at least one communications network connection, the communications hub being configured to receive information relating to an amount of DC electrical power to be delivered to a particular dispenser coupled to the charging station. Further still, the charging station includes a master controller configured to receive the information from the communications hub relating to the amount of DC electrical power to be delivered to the particular dispenser coupled to the charging station and provide a control signal to one of the at least one DC electrical power modules, the control signal being based on the information and being configured to control the amount of DC electrical power sent through one of the at least one DC electrical power modules.

A charging station includes an alternating current (AC) electrical power input and at least one direct current (DC) electrical power module coupled to the AC electrical power input. The charging station also includes at least one station output having a vehicle DC electrical power output, a communications output, and a dispenser DC electrical power output, the dispenser DC electrical power output being configured to be coupled to at least one dispenser. The charging station further includes a communications hub including at least one communications network connection, the communications hub being configured to receive information relating to an amount of DC electrical power to be delivered to a particular dispenser coupled to the charging station. Further still, the charging station includes a master controller configured to receive the information from the communications hub relating to the amount of DC electrical power to be delivered to the particular dispenser coupled to the charging station and provide a control signal to one of the at least one DC electrical power modules, the control signal being based on the information and being configured to control the amount of DC electrical power sent through one of the at least one DC electrical power modules.

A method for controlling a charge transfer of an electric vehicle using an electric vehicle charging station, a mobile device, and a cloud server is disclosed. The method includes: receiving, at a mobile device, a message for an electric vehicle of a user from the electric vehicle charging station, wherein a user of the mobile device is associated with the electric vehicle to be charged; sending, from the mobile device, the message for the electric vehicle of the user to the cloud server, wherein the charge transfer request relayed from the mobile device includes identification information; in response to a charging control signal being authorized using identification information received from the mobile device, receiving the charging control signal from the cloud server at the mobile device to be forwarded to the electric vehicle charging station, wherein the charging control signal is configured to adjust a charging parameter at the electric vehicle charging station.