A large-scale power generation method using electric locomotive-driven generators includes the following steps: step 1: setting up a circular railway, and running at least 10 electric locomotives on the circular railway; step 2: providing one or two 20 MW or 30 MW generators in each carriage; step 3: providing a multi-stage double-gear accelerated transmission device on a wheel axle, and driving a generator rotor to reach a rated speed for electricity production; and step 4: grid-connecting electricity produced by the generators, and allowing a small part of the produced electricity to pass through a shunt circuit to become a driving force for the continuous operation of the electric locomotives. And therefor the electromechanical interaction is formed.

A large-scale power generation method using electric locomotive-driven generators includes the following steps: step 1: setting up a circular railway, and running at least 10 electric locomotives on the circular railway; step 2: providing one or two 20 MW or 30 MW generators in each carriage; step 3: providing a multi-stage double-gear accelerated transmission device on a wheel axle, and driving a generator rotor to reach a rated speed for electricity production; and step 4: grid-connecting electricity produced by the generators, and allowing a small part of the produced electricity to pass through a shunt circuit to become a driving force for the continuous operation of the electric locomotives. And therefor the electromechanical interaction is formed.

The present disclosure includes systems, devices, and methods for identifying, detecting, and/or tracking rail features. In some aspects, a system includes a camera and a computer having at least one memory, at least one processor configured to receive a plurality of images from the camera, and for each of the images: assigning a location identifier and identifying one or more rail features that correspond to one of a plurality of predetermined rail features. In some systems, the at least one processor is configured to determine a location of each of the one or more identified rail features.

The present disclosure includes systems, devices, and methods for identifying, detecting, and/or tracking rail features. In some aspects, a system includes a camera and a computer having at least one memory, at least one processor configured to receive a plurality of images from the camera, and for each of the images: assigning a location identifier and identifying one or more rail features that correspond to one of a plurality of predetermined rail features. In some systems, the at least one processor is configured to determine a location of each of the one or more identified rail features.

A bogie assembly for a rail vehicle comprises a bogie frame, two wheel axles supporting the bogie frame, a primary of a linear induction motor and two motor mounts. The two motor mounts are located proximate a different extremity of the primary and support the linear induction motor underneath the bogie frame. Each one of the two motor mounts has a bogie interface, a motor interface, a first spring, a conical spring, a core pin and a nut. The first spring is connected to the bogie interface on the bogie side while the conical spring is connected to the same bogie interface on the motor side. The core pin extends sequentially from the motor interface through the conical spring, then through the bogie interface and finally through the first spring where it is held in place by the nut on the other side of the first spring.

A bogie assembly for a rail vehicle comprises a bogie frame, two wheel axles supporting the bogie frame, a primary of a linear induction motor and two motor mounts. The two motor mounts are located proximate a different extremity of the primary and support the linear induction motor underneath the bogie frame. Each one of the two motor mounts has a bogie interface, a motor interface, a first spring, a conical spring, a core pin and a nut. The first spring is connected to the bogie interface on the bogie side while the conical spring is connected to the same bogie interface on the motor side. The core pin extends sequentially from the motor interface through the conical spring, then through the bogie interface and finally through the first spring where it is held in place by the nut on the other side of the first spring.

The group of invention refers to the area of nuclear power engineering, particularly to auxiliary devices for nuclear power plants, namely to the devices for installation of the outer heat insulation of a nuclear reactor vessel, and can be used at nuclear plants for recovery annealing of welds and/or base metal of the VVER reactor pressure vessel. The task to be solved by the claimed group of inventions is to ensure the installation and disassembly of heat insulation of the outer surface of the VVER reactor pressure vessel in the confined space under the reactor and with the high level of ionizing radiation, as well as work performance in an automated mode, which excludes the exposure of personnel to ionizing radiation.

The technical result of the invention related to outer heat insulation of the nuclear reactor pressure vessel is the reduction of the temperature gradient through the thickness of the nuclear reactor vessel by heat insulation of the external reactor vessel surface, assurance of uniform physical properties for the reactor vessel metal and welds, and reduction of thermal impacts on the surrounding structures during recovery annealing of the welds and/or base metal of the VVER reactor vessel.

The technical result of the invention is provided by the fact that the external heat insulation of the nuclear reactor pressure vessel includes racks, supporting and heat insulation rings installed in series above each other on the upper support platforms of the racks and covering the nuclear reactor pressure vessel, with the racks evenly placed under the supporting and heat insulation rings on the floor of the space under reactor, each rack is provided with guide channels made on the upper part of the inner surface of the rack, and pivoted on the rack base, while the joint between the rack and the rack base is offset relative to the center of gravity of the rack with the possibility of deflection of the rack from the vertical position and its self-return to the vertical position, and the rack base is equipped with an adjustable screw support and has a support platform. Primarily supporting and heat insulation rings are made in the form of articulated sections of frame structure, made in the form of arched ring segments; heat insulation made of mullite-silica felt is fixed on the inner side of the frame of each heat insulation ring section; heat insulation blocks made in the form of triangular sheet piles of mullite-silica felt are additionally fixed on the upper surface of the upper heat insulation ring sections; support casings are made on the outer side of the frame of the support and heat insulation ring sections adjacent to the racks.

A shelving block comprises a first and second shelving units facing from opposite sides of an aisle. The first shelving unit defines a first crate storage location and a second crate storage location that different in height. The first crate storage location is accessible to a robot between a pair of neighboring horizontal rails having a first vertical spacing between them defining a height of the first crate storage location. The second crate storage location is accessible to the robot between another pair of neighboring horizontal rails having a second vertical spacing between them defining a height of the second crate storage location. The first vertical spacing is larger than the second vertical spacing. The robot carries crates according to instructions from a computerized control.

A large-scale power generation method using electric locomotive-driven generators includes the following steps: step 1: setting up a circular railway, and running at least 10 electric locomotives on the circular railway; step 2: providing one or two 20 MW or 30 MW generators in each carriage; step 3: providing a multi-stage double-gear accelerated transmission device on a wheel axle, and driving a generator rotor to reach a rated speed for electricity production; and step 4: grid-connecting electricity produced by the generators, and allowing a small part of the produced electricity to pass through a shunt circuit to become a driving force for the continuous operation of the electric locomotives. And therefor the electromechanical interaction is formed.

A large-scale power generation method using electric locomotive-driven generators includes the following steps: step 1: setting up a circular railway, and running at least 10 electric locomotives on the circular railway; step 2: providing one or two 20 MW or 30 MW generators in each carriage; step 3: providing a multi-stage double-gear accelerated transmission device on a wheel axle, and driving a generator rotor to reach a rated speed for electricity production; and step 4: grid-connecting electricity produced by the generators, and allowing a small part of the produced electricity to pass through a shunt circuit to become a driving force for the continuous operation of the electric locomotives. And therefor the electromechanical interaction is formed.