A power transmission shaft comprises a shaft unit interposed between first and second shafts; an engaged portion provided on one end of the second shaft and having an annular stepped part provided between a smaller diameter portion and a larger diameter portion; and an engaging portion provided on one end of the shaft unit and joinable with the engaged portion to rotate together about a common rotation axis, wherein the engaging portion comprises a cylindrical base portion that rotates together with the shaft unit, an elastically shrinkable cylindrical portion that is provided on one axial end of the cylindrical base portion to project toward the engaged portion and catching pawls that are provided by the elastically shrinkable cylindrical portion and latchingly engageable with the annular stepped part when the engaged portion and the engaging portion are coaxially arranged and joined with each other.

A power transmission shaft comprises a shaft unit interposed between first and second shafts; an engaged portion provided on one end of the second shaft and having an annular stepped part provided between a smaller diameter portion and a larger diameter portion; and an engaging portion provided on one end of the shaft unit and joinable with the engaged portion to rotate together about a common rotation axis, wherein the engaging portion comprises a cylindrical base portion that rotates together with the shaft unit, an elastically shrinkable cylindrical portion that is provided on one axial end of the cylindrical base portion to project toward the engaged portion and catching pawls that are provided by the elastically shrinkable cylindrical portion and latchingly engageable with the annular stepped part when the engaged portion and the engaging portion are coaxially arranged and joined with each other.

A disclosed submersible pump apparatus includes a three-dimensional frame, a pump housing, a drive shaft, an impeller, and first and second motors. The impeller is mounted on the driveshaft within the pump housing and is driven by one or both of the motors. The first motor is connected to a first end of the drive shaft and the second motor connected a second end of the drive shaft. The first and second motors are hydraulic motors and in a first configuration, the first and second motors are configured to cooperatively rotate the drive shaft with hydraulic fluid supplied to and removed from the first and second motors using a parallel fluidic connection. In a second configuration, only one of the motors has a drive gear and drives the drive shaft while the second motor does not have a drive gear and acts as a frictionless bearing supporting the drive shaft.

A disclosed submersible pump apparatus includes a three-dimensional frame, a pump housing, a drive shaft, an impeller, and first and second motors. The impeller is mounted on the driveshaft within the pump housing and is driven by one or both of the motors. The first motor is connected to a first end of the drive shaft and the second motor connected a second end of the drive shaft. The first and second motors are hydraulic motors and in a first configuration, the first and second motors are configured to cooperatively rotate the drive shaft with hydraulic fluid supplied to and removed from the first and second motors using a parallel fluidic connection. In a second configuration, only one of the motors has a drive gear and drives the drive shaft while the second motor does not have a drive gear and acts as a frictionless bearing supporting the drive shaft.

A disclosed submersible pump apparatus includes a three-dimensional frame, a pump housing, a drive shaft, an impeller, and first and second motors. The impeller is mounted on the driveshaft within the pump housing and is driven by one or both of the motors. The first motor is connected to a first end of the drive shaft and the second motor connected a second end of the drive shaft. The first and second motors are hydraulic motors and in a first configuration, the first and second motors are configured to cooperatively rotate the drive shaft with hydraulic fluid supplied to and removed from the first and second motors using a parallel fluidic connection. In a second configuration, only one of the motors has a drive gear and drives the drive shaft while the second motor does not have a drive gear and acts as a frictionless bearing supporting the drive shaft.

A disclosed submersible pump apparatus includes a three-dimensional frame, a pump housing, a drive shaft, an impeller, and first and second motors. The impeller is mounted on the driveshaft within the pump housing and is driven by one or both of the motors. The first motor is connected to a first end of the drive shaft and the second motor connected a second end of the drive shaft. The first and second motors are hydraulic motors and in a first configuration, the first and second motors are configured to cooperatively rotate the drive shaft with hydraulic fluid supplied to and removed from the first and second motors using a parallel fluidic connection. In a second configuration, only one of the motors has a drive gear and drives the drive shaft while the second motor does not have a drive gear and acts as a frictionless bearing supporting the drive shaft.

A method for checking the design of locking assemblies is provided. A pressure on each contact surface and a torque that can be transferred by a spindle and a bushing after locking assemblies are locked are calculated. The calculated torque is compared with the designed maximum transferable torque to calculate a torque safety coefficient. Based on a minimum fit clearance, a resultant stress of components is calculated and is compared with a yield strength of the material of the components to calculate a strength safety coefficient of the components. A pre-tightening force of the bolts is obtained according to a given pre-tightening moment of the bolts. A maximum equivalent stress of the bolts is calculated to obtain a safety coefficient of the bolts. This method is able to be applied to the manufacturing of the locking assemblies.

The disclosure provides an assembly method of inner ring threaded-connection component device of wind-power locking plate. An internal thread (5) is processed in an inner hole of an inner ring flange (2), an external thread (4) is processed on an outer conical surface (8) at an large opening end of an inner ring (3), and after the processing of the internal thread (5) and the processing of the external thread (4) are respectively completed, an inner ring assembly formed by integral threaded connection of the inner ring flange (2) and the inner ring (3) is connected with the outer ring (1) through bolts so as to form a locking plate component; a shaft sleeve (9) sleeves the locking plate component to ensure that the inner hole of the inner ring (3) matches with the outer circumference of the shaft sleeve (9).

The present invention discloses a method for checking the design of locking assemblies, comprising: calculating a pressure on each contact surface and a torque that can be transferred by a spindle and a bushing after locking assemblies are locked, and comparing the calculated torque with the designed maximum transferable torque to calculate a torque safety coefficient; with a minimum fit clearance, calculating a resultant stress of components, and comparing the resultant stress with a yield strength of the material of the components to calculate a strength safety coefficient of the components; and obtaining a pre-tightening force of the bolts according to a given pre-tightening moment of the bolts, calculating a maximum equivalent stress of the bolts, and obtaining a safety coefficient of the bolts. This method in the present invention can effectively verify the rationality of design of locking assemblies, reduce the manufacture risk and increase the yield of products.

The disclosure provides an assembly method of inner ring threaded-connection component device of wind-power locking plate. An internal thread (5) is processed in an inner hole of an inner ring flange (2), an external thread (4) is processed on an outer conical surface (8) at an large opening end of an inner ring (3), and after the processing of the internal thread (5) and the processing of the external thread (4) are respectively completed, an inner ring assembly formed by integral threaded connection of the inner ring flange (2) and the inner ring (3) is connected with the outer ring (1) through bolts so as to form a locking plate component; a shaft sleeve (9) sleeves the locking plate component to ensure that the inner hole of the inner ring (3) matches with the outer circumference of the shaft sleeve (9).