SU655003A1 - Apparatus for contact-free electric power transmission from stationary object to movable one - Google Patents

Description

more completely in the form of a carrier 5 mounted rotatably around the non-movable and movable drums. On the carrier 5, symmetrically on opposite sides with respect to the longitudinal axis of the device, movable carriages with rollers 6 and 7 are installed to guide the cables 8 and 9, which are drawn on these rollers.

Cables 8 and 9 at one end are fixed in a cable box 10 located on the drum 1 of the winch, and wound on a movable drum 4 turn to turn, and the cable 8 from the external, and the cable 9 from the inner ends towards each other. Next, cables 8 and 9 round the rollers 6 and 7, respectively, and are wound on a stationary drum 3, the cable 8 being from the outer cable and 9 from the inner ends, again towards one another. Next, the cables through the hollow shaft of the stationary drum 3 are brought to the stationary cable box 11, to which the equipment and power sources are connected. The direction of winding each of the cables on the movable and stationary drums is opposite, that is, if the cables 8 and 9 on the movable drum are wound on the left helix, then on the stationary 3 on the right. The total number of turns of cable 8 on the movable and untapped drums is equal to the total number of turns of cable 9 on the same drums.

A gear 12 is mounted on the stationary drum 3, with which the gears 13 and 14 of the carriage drive of the guide rollers 6 and 7 are engaged, which allows the rollers to move along the drums during cable rewinding.

The device works as follows.

When the drum 1 is rotated on winding the cable 2, the drum 4 also rotates with it. The drum 5, rotating, winds the cable 9, which is loaded onto the roller 7, due to the tension that arose in it when winding the drum 3. the carrier 5 rotates in the same direction as the movable drum, but at a speed two times smaller. The rotating carrier 5 will wind the cable 9 from the stationary drum 3, at the same time winding it, as indicated above, on the movable drum 4.

At the same time, the carrier 5 uses the roller 6 to wind the cable 8 from the movable drum 4 and winds it onto the stationary drum 3.

Thus, when the drum 1 rotates on the descent, the cable 9, winding from the moving drum 3, will free up space on it for simultaneous winding on the cable 8, and the cable 8, winding on the drum 3, will free up space on the moving drum to wind the cable 9.

There is a counter rewind of cables. The rotating carrier forces the gears 13 and 14 to run in a fixedly mounted gear 12 and, thus, causes the spindle screws 15 and 16 to rotate. The spindle screws move the carriages with the guide rollers 6 and 7 along the drums, providing a coil to the coil rewindable cables. In the considered interaction, the leading element is the left branch of the cable 9.

After winding the entire required length of cable 2, cable 9 is rewound from a stationary drum to

movable, and cable 8 from the movable drum to the fixed.

When winding the cable 2, repetition of the cables 8 and 9 occurs in the opposite direction, thus providing

contactless current transfer from the vessel to the towed or lowered object, and turn. In this case, the leading element for the carrier 5 will be the left branch of the cable 8. Such a structural solution of the device allows an increase in the number of simultaneously transmitted communications. Simplification of the design is ensured by balancing the carrier due to the symmetrical installation of the rollers, in connection with which counterweights are not required, and due to the exclusion from the design of the drive mechanism of the carrier, which is carried out by rewinding cables.

Claims (2)

1. Authors certificate of the USSR Up to 412650, cl. H 02G 11/02, 1971. 2. The author's certificate of the USSR with 369042, cl. H 02G 11/02, 1970. to