A lifting device and a washing machine to resolve difficulty moving a washing machine. The device includes a driving device, a connection rod, a first lever, a second lever and support legs, where the driving device is on the bottom of a washing machine body; the support legs are arranged at the bottom of the body; the driving device is connected to a first end of the first lever and to a first end of the second lever in a driving manner, by the connection rod; a second end of the first lever is connected to one of the support legs, and a pivoting end of the first lever is connected to the washing machine body; and a second end of the second lever is connected to one of the support legs, and a pivoting end of the second lever is connected to the washing machine body.

The embodiments of the disclosure provide a robot and a splicing method thereof, and a robot splicing system. The robot includes at least two sub-robots, each of the sub-robots including a body, a mobile member located at the bottom of the body, at least one first connecting mechanism and at least one second connecting mechanism located on different sides of the body, the first connecting mechanism of at least one of the sub-robots being configured such that it may be in a fit connection with the second connecting mechanism of at least one other sub-robot, and the second connecting mechanism being configured such that it may be in a fit connection with the first connecting mechanism of at least one other sub-robot.

The embodiments of the disclosure provide a robot and a splicing method thereof, and a robot splicing system. The robot includes at least two sub-robots, each of the sub-robots including a body, a mobile member located at the bottom of the body, at least one first connecting mechanism and at least one second connecting mechanism located on different sides of the body, the first connecting mechanism of at least one of the sub-robots being configured such that it may be in a fit connection with the second connecting mechanism of at least one other sub-robot, and the second connecting mechanism being configured such that it may be in a fit connection with the first connecting mechanism of at least one other sub-robot.

An automobile includes a plurality of frame-integrated hydraulic jacks includes a trunk mounted control panel in electrical communication with a power source and a plurality of jacks each being located beneath the automobile frame adjacent each wheel of the automobile. A plurality of flashing illumination is disposed upon the base of each jack and are in electrical communication with the control panel. The control panel permits a user to selectively raise or lower the automobile by the actuation of the plurality of jacks.

An automobile includes a plurality of frame-integrated hydraulic jacks includes a trunk mounted control panel in electrical communication with a power source and a plurality of jacks each being located beneath the automobile frame adjacent each wheel of the automobile. A plurality of flashing illumination is disposed upon the base of each jack and are in electrical communication with the control panel. The control panel permits a user to selectively raise or lower the automobile by the actuation of the plurality of jacks.

A fully electric lift device includes a base assembly, a lift assembly, a platform assembly, tractive elements, an energy storage device, and a control system. The lift assembly is coupled with the base assembly and is driven by an electric linear actuator for a lifting function. The platform assembly is positioned at a top of the lift assembly and can be raised or lowered as the lift assembly performs the lifting function. The tractive elements are rotatably coupled with the base assembly and can be driven by an electric wheel motor to perform a driving function. The control system includes a controller that operates the electric wheel motor and the electric linear actuator to perform the driving function and the lifting function using power drawn from the energy storage device. The lift assembly and the tractive elements use only electrical energy to perform the lifting and driving functions.

A fully electric lift device includes a base assembly, a lift assembly, a platform assembly, tractive elements, an energy storage device, and a control system. The lift assembly is coupled with the base assembly and is driven by an electric linear actuator for a lifting function. The platform assembly is positioned at a top of the lift assembly and can be raised or lowered as the lift assembly performs the lifting function. The tractive elements are rotatably coupled with the base assembly and can be driven by an electric wheel motor to perform a driving function. The control system includes a controller that operates the electric wheel motor and the electric linear actuator to perform the driving function and the lifting function using power drawn from the energy storage device. The lift assembly and the tractive elements use only electrical energy to perform the lifting and driving functions.

A telescopic pipe includes a base pipe having a base inner pipe rotated by external force, and a base outer pipe arranged to receive the base inner pipe; a connecting pipe having a connecting inner pipe coupled to the base inner pipe to be extendable to transfer rotational force, and a connecting outer pipe screw-coupled to the inner circumferential surface of the base outer pipe to be extendable; and a finishing pipe including a finishing inner pipe coupled to the connecting inner pipe to be extendable and to be rotated, and a finishing outer pipe that is interlocked by means of rotation of the finishing inner pipe and is screw-coupled to the inner circumferential surface of the connecting outer-pipe to be extendable, wherein the connecting outer pipe is interlocked by the rotational force of the extended finishing outer pipe and thus is extended and retracted along the base outer pipe.

A lift system and method for installation and removal of a combustion can from a turbomachine are provided. The lift system includes a rail, a portable cart assembly, and a slide assembly. The portable cart assembly includes a combustion can cradle assembly coupled to a telescopic member. The combustion can cradle assembly is configured to removably couple to a combustion can of the turbomachine. The slide assembly is removably couplable to the portable cart assembly and the rail. The slide assembly is movable with the portable cart assembly along the rail to adjust a position of the combustion can cradle assembly.

A lift system and method for installation and removal of a combustion can from a turbomachine are provided. The lift system includes a rail, a portable cart assembly, and a slide assembly. The portable cart assembly includes a combustion can cradle assembly coupled to a telescopic member. The combustion can cradle assembly is configured to removably couple to a combustion can of the turbomachine. The slide assembly is removably couplable to the portable cart assembly and the rail. The slide assembly is movable with the portable cart assembly along the rail to adjust a position of the combustion can cradle assembly.