An elevator system includes a car, configured to travel through a hoistway; a first stationary drive unit, configured to be mounted in a hoistway, a first movable drive unit, configured to be functionally coupled to the car and to the first stationary drive unit, and a second movable drive unit, configured to be functionally coupled to the car and to the first stationary drive unit.

An apparatus and process for lifting heavy objects by capturing mechanical work from the buoyant energy of liquid displacement. The apparatus comprises one or more bodies of liquid, collapsible liquid-displacement displacement vessel, and lifting force transfer means to the object, in use, the weight of the object to be lifted is secured onto the lifting platform and leveraged by the force transfer means to draw gas into the displacement vessel. Once the displacement vessel is full of gas, it will reverse the force transfer means to lift the object to the top of the liquid. Once the lifted object is secured at the elevated position, a gas release valve releases the gas and the displacement vessel collapses and sinks back down to the bottom of the liquid and the process can be repeated as necessary.

A power generation system including a partially enclosed container assembly housing a plurality of spherical balls at a container height disposed above a ground surface, each of the plurality of spherical balls having a ball weight. The power generation system also includes a conveyor assembly with a conveyor-drive system having a plurality of ball-catch members. The conveyor assembly includes a proximal end coupled to the container assembly, a distal end, and a conveyer length separating the proximal and distal ends. The conveyor assembly spans downwardly from the container assembly at a location below the container height and is operably configured, via the ball-catch members of the conveyor-drive system, to transport the spherical balls. A generator is operably coupled to the conveyor-drive system and is operably configured to produce electricity. The power generation system also includes a lift assembly having a lift-drive system spanning from a ball-receiving position to a ball-dispersing position with a height disposed above the ground surface that is greater than the container height. The lift-drive system includes a ball-platform sized to hold the plurality of spherical balls and a platform operably coupled to the lift-drive system that is sized to hold a plurality of users. The platform includes a raised position and a lowered position along a lift translation path. The raised position includes a height disposed above the ground surface that is greater than the container height. Movement of the platform of the lift-drive system along the lift translation path is operably configured to move the ball-platform of the lift-drive system along ball-platform translation path to transport the spherical balls to the ball-dispersing position.

A lifting system for post frame construction comprises a winch system coupled to a frame, a first bracket configured to be secured to a portion of a roof framing system, and a pulley system comprising at least two pulley wheels mounted on a second bracket. The frame is configured to be secured to a lower portion of a column of a building structure and the second bracket is configured to be secured to a top of the column.

Provided is a tower lift including a rail module extending in a vertical direction, a carriage module provided to be movable along the rail module by magnetic levitation, and a brake device integrated with the carriage module and configured to move along the rail module, wherein the brake device includes a base body structure having a relative position fixed with respect to the carriage module, and providing an inclined surface, and a brake structure moving along the inclined surface of the base body structure to stop a drop of the carriage module by selectively coming in contact with the rail module, the rail module is between the base body structure and the brake body so that the brake structure is in contact with both side walls of the rail module, and the brake structure stops the drop of the carriage module when power for driving the tower lift is cut off.

An energy-saving traction-type elevator and an energy-saving method therefor are presented. The traction-type elevator includes at least one counterbalance unit, each counterbalance unit comprising a traction machine. The traction-type elevator further includes an automatic transmission, a hoist-type lifting mechanism, a power-generating electric motor, and a controller provided in a machine room, and a car, a fixed counterweight and a balancing counterbalance provided in an elevator shaft. The energy-saving method applies the principle of moment balance, whereby adding a separate elevator balancing counterbalance to achieve intelligent counterbalancing of the elevator so that the elevator achieves relative balance, thereby reducing the traction moment and rate of work of the traction machine. When the potential energy of the elevator balancing counter-balance builds up to a high position, the power-generating electric motor can perform centralized power generation, aiding in energy recovery and use.

A nuclear power plant having buried buildings that include a containment building housing a nuclear reactor, a power generation building housing turbines, and a nuclear material storage building. A borated cooling water tank is located above the containment building and can gravity feed water thereto through cooling pipes. Steam exhaust pipes extend from the containment building to the bottom of the water tank. A float and valve arrangement provides seawater to keep the water tank at a constant water level. Horizontal tunnels have manually operated hatches to isolate the different buildings from one another. Vertical tunnels have gravity elevators.

A power generation system including a partially enclosed container assembly housing a plurality of spherical balls at a container height disposed above a ground surface, each of the plurality of spherical balls having a ball weight. The power generation system also includes a conveyor assembly with a conveyor-drive system having a plurality of ball-catch members. The conveyor assembly includes a proximal end coupled to the container assembly, a distal end, and a conveyer length separating the proximal and distal ends. The conveyor assembly spans downwardly from the container assembly at a location below the container height and is operably configured, via the ball-catch members of the conveyor-drive system, to transport the spherical balls. A generator is operably coupled to the conveyor-drive system and is operably configured to produce electricity. The power generation system also includes a lift assembly having a lift-drive system spanning from a ball-receiving position to a ball-dispersing position with a height disposed above the ground surface that is greater than the container height. The lift-drive system includes a ball-platform sized to hold the plurality of spherical balls and a platform operably coupled to the lift-drive system that is sized to hold a plurality of users. The platform includes a raised position and a lowered position along a lift translation path. The raised position includes a height disposed above the ground surface that is greater than the container height. Movement of the platform of the lift-drive system along the lift translation path is operably configured to move the ball-platform of the lift-drive system along ball-platform translation path to transport the spherical balls to the ball-dispersing position.

The present invention provides a variable mass elevator apparatus and method of operation, wherein the apparatus comprises an electronic scale, an elevator car, a traction sheave, a control computer, a mass storage area, a mass, a mass conveyor, a floor control panel outside of the elevator. When a passenger desires to operate the elevator, the passenger steps on the electronic scale and chooses a floor on the floor control panel, wherein the floor control panel has buttons for each floor. The electronic scale relays the weight of the passenger to the control computer, and the floor control panel relays the desired floor to the control computer. The control computer instructs a mass conveyer to couple a mass corresponding to the weight of the passenger to the elevator cable to act as a counterweight and equalize the potential energy of the elevator according to the desired floor of the passenger and the weight of the passenger.