A hoist system and a method for lifting and lowering an object such as a boat include a support structure, a support member supported by the support structure and a hoisting assembly. The hoisting assembly includes an attachment assembly and a set of at least three flexible members operably coupled to the support member and the attachment assembly to retract and extend the attachment assembly vertically relative to a reference axis. The hoisting assembly is supported by the support structure and configured with the support member so as to space apart the flexible members from each other, and wherein each flexible member defines an oblique angle with the reference axis parallel to the vertical reference axis.

Disclosed is a winch with a spool having an axis of rotation and a helical groove formed thereon and a line around the spool in the helical groove. The winch also includes a motor configured to rotate the spool in a first direction to wind the line on the spool and a second direction to unwind the line from the spool. The helical groove includes a line cradle shaped to carry the line with a portion of the line protruding from the helical groove, and a channel extending below the line cradle. A portion of the channel is not occupied by the line. The winch also includes a line guide adjacent to the spool and configured to move axially along the spool. The line guide includes a tab that engages the channel to cause the line guide to move axially along the spool to wind or unwind the line.

A winch is described that includes a motor and a driveshaft coupled to the motor for rotation about its axis. A first and second spool are mounted to the drive shaft so that rotation of the driveshaft causes rotation of the first and second spool. A first line is attached to the first spool and a second line is attached to the second spool. First and second line guides are configured to wind the lines in a helical path on the respective spools when the driveshaft is rotated in one direction and to unwind the lines from the helical path when the driveshaft is rotated in an opposite direction. Each line guide is further configured to translate axially along the first spool to facilitate winding and unwinding along the respective helical path.

A winch is described that includes a motor and a driveshaft coupled to the motor for rotation about its axis. A first and second spool are mounted to the drive shaft so that rotation of the driveshaft causes rotation of the first and second spool. A first line is attached to the first spool and a second line is attached to the second spool. First and second line guides are configured to wind the lines in a helical path on the respective spools when the driveshaft is rotated in one direction and to unwind the lines from the helical path when the driveshaft is rotated in an opposite direction. Each line guide is further configured to translate axially along the first spool to facilitate winding and unwinding along the respective helical path.

A winch is disclosed having a motor, a spool rotated by the motor, and a line carried by the spool. Rotating the spool in a first, or winding direction causes the line to wind around the spool, and rotating the spool in a second, or unwinding direction causes the line to unwind from the spool. The winch also includes a tensioning device spaced apart from the spool, which tensioning device comprises a tensioning wheel that engages the line and is configured to apply tension to the line as it is being unwound.

The present invention relates to a hoisting winch, in particular to a hoisting gear winch, having a hoisting drum whose winding region is bounded by two lateral flanged wheels, wherein at least one further flanged wheel is provided between the lateral flanged wheels for dividing the winding region into at least two part winding regions, wherein the cable can be guided beyond the named further flanged wheel into the at least two part winding regions. It is suggested in accordance with the invention to move the hoisting drum and/or a transverse cable guide arranged in front of the hoisting drum transversely to the longitudinal direction of the running in/running off cable approximately in the longitudinal direction of the drum and/or to adjust the angular position of the hoisting drum transversely to the longitudinal direction of the drum with respect to at least one transverse axis.

The present invention relates to a hoisting winch, in particular to a hoisting gear winch, having a hoisting drum whose winding region is bounded by two lateral flanged wheels, wherein at least one further flanged wheel is provided between the lateral flanged wheels for dividing the winding region into at least two part winding regions, wherein the cable can be guided beyond the named further flanged wheel into the at least two part winding regions. It is suggested in accordance with the invention to move the hoisting drum and/or a transverse cable guide arranged in front of the hoisting drum transversely to the longitudinal direction of the running in/running off cable approximately in the longitudinal direction of the drum and/or to adjust the angular position of the hoisting drum transversely to the longitudinal direction of the drum with respect to at least one transverse axis.

A method for replacing a length of a wire/cable in a hoisting system. The wire/cable extends from a storage drum to a winch. The method includes removing at least one lock which prevents a deadline anchor arranged between the storage drum and the winch from rotating, reeling onto the storage drum a first length of the wire/cable with a simultaneous coordinated operation of the deadline anchor and the storage drum, the simultaneous coordinated operation being controlled so that the wire/cable is in a continuous tension between the deadline anchor and the storage drum, securing the wire/cable to an attachment point, cutting a section of the wire/cable between the attachment point and the winch and removing the cut section of the wire/cable, reattaching the wire/cable remaining to the winch, reeling out a second length of the wire/cable from the storage drum, and securing the wire/cable to the deadline anchor.

A method for replacing a length of a wire/cable in a hoisting system. The wire/cable extends from a storage drum to a winch. The method includes removing at least one lock which prevents a deadline anchor arranged between the storage drum and the winch from rotating, reeling onto the storage drum a first length of the wire/cable with a simultaneous coordinated operation of the deadline anchor and the storage drum, the simultaneous coordinated operation being controlled so that the wire/cable is in a continuous tension between the deadline anchor and the storage drum, securing the wire/cable to an attachment point, cutting a section of the wire/cable between the attachment point and the winch and removing the cut section of the wire/cable, reattaching the wire/cable remaining to the winch, reeling out a second length of the wire/cable from the storage drum, and securing the wire/cable to the deadline anchor.

A management system for a closed environmental facility includes one or more motorized tubular hoist mechanisms operable to adjust the height of environmental modules above one or more groups of plants. A central controller provides signals over a wireless communication network to command the hoist mechanisms to move the environmental modules to a desired position. In further embodiments, environmental sensors provide data to the central controller and the controller automatically calculates desired positions of the environmental modules based on the data and commands the hoist mechanisms to achieve the desired positioning.