A tethered charging and recharging (TCR) drone assembly system is provided. The TCR drone assembly system may be a nurse vehicle-based, a master/slave vehicle-based, a stationary structure and/or free standing TCR drone assembly system. The TCR drone assembly system is especially suitable for use on moving vehicles, for example, a self-propelled conventional type vehicle operated by an operator and/or autonomous or slave autonomous vehicle with no operator on board. The TRC drone assembly system may quickly couple and may deliver energy charges, recharges or other types of power propellants to vehicles while the vehicles are stationary or in motion. The assemblies are especially suitable for providing power to vehicles when only limited downtime of the vehicles is desired. The assemblies are suitable for use in, for example, the agricultural, construction, defense or other industries.

A mobile solar charging facility. The present invention relates to power supply and charging techniques for a mobile electric apparatus during movement, and in particular to such a facility having a combined technique of a solar photovoltaic battery and solar thermal power generation, and matching techniques and extended applications related to light compensation, energy storage, etc. The present invention is aimed at solving the problem of charging an electric vehicle when traveling. A highly cost-effective solar power source is used for power supply. The technical solutions of a contact rail and a collector shoe are used for mobile power supply and charging. An arc extinction circuit and an energy storage super-capacitor are provided in a line, and a safety protection measure is provided. A condenser lens and a compensation lens which can increase a power generation amount and do not need to be tracked as provided for solar power generation.

A mobile solar charging facility. The present invention relates to power supply and charging techniques for a mobile electric apparatus during movement, and in particular to such a facility having a combined technique of a solar photovoltaic battery and solar thermal power generation, and matching techniques and extended applications related to light compensation, energy storage, etc. The present invention is aimed at solving the problem of charging an electric vehicle when traveling. A highly cost-effective solar power source is used for power supply. The technical solutions of a contact rail and a collector shoe are used for mobile power supply and charging. An arc extinction circuit and an energy storage super-capacitor are provided in a line, and a safety protection measure is provided. A condenser lens and a compensation lens which can increase a power generation amount and do not need to be tracked as provided for solar power generation.

The invention relates to a line section for the operation of electrically driven rail vehicles, with a track which exhibits two parallel rails, with a contact line borne by an insulator, said contact line being arranged on one side of the track in a spatial region extending parallel to the rails, wherein the contact line is intended to supply current-collectors of the electrically driven rail vehicles with current and to support said current-collectors from underneath, and wherein the contact line and the insulator bearing the contact line are intermittently interrupted or not interrupted.

The invention is distinguished in that a support device which is non-functional for the power supply of the rail vehicle is arranged on the other side of the track in a second spatial region extending parallel to the rails, said support device being intended to support current-collectors of the electrically driven rail vehicles from underneath without supplying them with current.

A charging module for an electric vehicle includes an enclosure having a plurality of sides and an at least partially open top, the enclosure defining a hollow interior; a conductor rail disposed in the at least partially open top of the enclosure, the conductor rail being configured to be placed in electric communication with an electrical power source; and at least one external insulator disposed in the at least partially open top of the enclosure adjacent to the conductor rail. The at least one external insulator is disposed between the conductor rail and at least one of the sides of the enclosure. The conductor rail is configured to transmit electrical energy from the electrical power source to the electric vehicle.

An apparatus includes a chassis configured to move back and forth along multiple rails. The apparatus also includes electrical contacts configured to form electrical connections to the rails. The apparatus further includes a power converter/conditioner configured to receive power from the rails via the electrical contacts and to convert the power into a different form and/or condition the power. In addition, the apparatus includes one or more sensors configured to measure at least one characteristic of a material, where the one or more sensors are configured to operate using the power from the power converter/conditioner. The electrical contacts could touch the rails and receive the power directly from the rails. The electrical contacts could also touch rail contacts and receive the power indirectly from the rails via the rail contacts.

An apparatus includes a chassis configured to move back and forth along multiple rails. The apparatus also includes electrical contacts configured to form electrical connections to the rails. The apparatus further includes a power converter/conditioner configured to receive power from the rails via the electrical contacts and to convert the power into a different form and/or condition the power. In addition, the apparatus includes one or more sensors configured to measure at least one characteristic of a material, where the one or more sensors are configured to operate using the power from the power converter/conditioner. The electrical contacts could touch the rails and receive the power directly from the rails. The electrical contacts could also touch rail contacts and receive the power indirectly from the rails via the rail contacts.

A guide track includes a guide rail having a guide groove opened upward in which guide wheels are inserted, and formed with guide surfaces for causing each of the guide wheels to roll at both sides of a traveling course in a width direction; conductor rails that are placed at both sides of an outside of the traveling course in the width direction with respect to the guide groove to perform contact electricity supply by pressing a power collection shoe of a power collector of a track-based vehicle; a first insulator that supports the conductor rails with respect to the guide rail; and insulation plates that are provided at both sides of the conductor rail in the width direction, and are provided in parallel to the conductor rail and in parallel to a pressing direction of the power collection shoe.

A guide track includes a guide rail having a guide groove opened upward in which guide wheels are inserted, and formed with guide surfaces for causing each of the guide wheels to roll at both sides of a traveling course in a width direction; conductor rails that are placed at both sides of an outside of the traveling course in the width direction with respect to the guide groove to perform contact electricity supply by pressing a power collection shoe of a power collector of a track-based vehicle; a first insulator that supports the conductor rails with respect to the guide rail; and insulation plates that are provided at both sides of the conductor rail in the width direction, and are provided in parallel to the conductor rail and in parallel to a pressing direction of the power collection shoe.

In a method of operating a motor vehicle driven electrically, at least temporarily, on a roadway, the motor vehicle is moved fully autonomously by a control unit in response to a command for automatic operating mode. After a charging arm of the motor vehicle has been extended, a lateral control of the motor vehicle is executed to bring the extended charging arm into electric contact with a charging line arranged at or on the roadway. As a result, electric energy provided from the charging line to the charging arm is used for charging an energy accumulator of the motor vehicle and/or operating a drive device of the motor vehicle for moving the motor vehicle. A longitudinal control of the motor vehicle is executed to thereby maintain a predefined longitudinal speed of the motor vehicle until a distance of the motor vehicle reaches a predefined minimum distance to a leading vehicle.