RU144443U1 - SELF-REGULATING STEP ROW SCREW - Google Patents

Abstract

1. A propeller of a self-adjusting step, comprising a hub with a copier bolt and mounting holes, in which the axis of the screw blades are made, made with spiral slots, characterized in that the mounting holes are provided with bushings, the spiral slot is made through, and the screw blades are connected with split axles connections. 2. Propeller according to claim 1, characterized in that the axis of the blades are connected to the blades by a detachable connection. 3. Rowing screw according to claim 2, characterized in that the detachable connection is made in the form of a guide located on the lower part of the blade, which is fixed in the groove of the axis. A propeller according to claim 3, characterized in that one of the ends of the guide is open for the guide to enter the groove of the axis of the blade. 5. Propeller according to claim 3, characterized in that the connection of the guide blade in the groove of the axis is fixed by a screw. 6. A propeller according to claim 1, characterized in that the axis of the blades are installed in the mounting holes of the hub of the screw through the bushings forming friction pairs. A propeller according to claim 6, characterized in that the bushings are made of a material with a low coefficient of friction and having anti-corrosion properties. Rowing screw according to claim 1, characterized in that the copier bolt interacts with the side surfaces of the slot of the spiral axis of the blade through a cylindrical sleeve. Rowing screw according to claim 8, characterized in that the cylindrical sleeve is made of a material with a low coefficient of friction and having anti-corrosion properties.

Description

The utility model relates to ship propulsion, in particular, to propellers, the blades of which are self-adjusting relative to the aquatic environment.

Known self-adjusting pitch screw (patent US 2052454), containing the hub of the screw, rotary screw blades on the axes, made with the possibility of longitudinal movement of the blade, increasing the diameter of the screw, and around the axis, changing the pitch of the blade. The blade moves along its axis and the blade pitch changes along a spiral slot made in the axis itself, while a copier bolt is fixed in the hub. The blades are made integral with the axes and are interconnected by a radial ring. Depending on the mode of rotation of the screw, the blades take a predetermined position, i.e. self-regulate.

The disadvantage of this device is the design complexity, which consists in a large number of fasteners, the presence of a spring.

A self-adjusting pitch propeller device is also known (US Pat. No. 5,022,820). This device is closest to the proposed utility model and is selected as a prototype. The screw contains a hub with mounting holes in which rotary screw blades are mounted on the axes, capable of longitudinal movement of the blade, increasing the diameter of the screw, and around the axis, changing the pitch of the blade. The blades contain a vane section, which helps the blades to take an optimal position. The movement of the blade in the axial direction and the pitch change of the blade occurs along a non-through spiral slot made in the axis itself, while a copier bolt is fixed in the hub, which enters the spiral slot with its end part. The blades are made integral with the axes. Depending on the mode of rotation of the screw, the blades take a predetermined position, i.e. self-regulate by sliding the end of the copier bolt in a spiral slot. To synchronize the position of the blade articulated with a radial ring.

The disadvantages of this design are the possibility of "biting" the end face of the copier bolt in the axial spiral spline as a result of the possible warping of the axis in the mounting bushing, as well as the complexity of replacing the damaged blade caused by removing the screw from the drive shaft and completely disassembling it.

The technical result of the claimed utility model is the exclusion of the possibility of "biting" a copier bolt in a spiral slot and simplifying the replacement of a damaged blade.

The claimed technical result is achieved by the fact that the spiral slot on the axis of the blade is made through, and the copier bolt, motionlessly installed in the hub, interacts with its cylindrical part only with the side surfaces of the slot. The axis of the blade is fixed in the mounting hole of the screw hub through bushings made of a material with a low coefficient of friction and having anti-corrosion properties, for example, polypropylene. The blade of the screw is made separately from the axis and connected to it by a detachable connection, for example, the blade in its lower part is provided with a guide, which is placed in the groove of the axis of the screw located on the end of the axis, protruding outside the sleeve. The interaction of the copier bolt with the side surfaces of the slot can be carried out through a cylindrical sleeve made of a material with a low coefficient of friction.

In FIG. 1 is a perspective view of a propeller of a self-adjusting pitch; FIG. 2 is a sectional view of the device, in FIG. 3 shows a perspective view of an axis-blade assembly.

The self-adjusting pitch propeller contains a hub 1 with mounting holes 2, into which bushings 3 are mounted, forming a friction pair and made of material with a low coefficient of friction and having anti-corrosion properties. The rotary blade 4 of the screw on the axes 5 is arranged to radially move the blade 4 of the screw, increasing the diameter of the screw, and with the possibility of changing the pitch of the blade 4 of the screw. The movement of each blade 4 of the screw occurs through a through spiral slot 6 made in the corresponding axis 5 along the copy bolt 7 fixed in the hub. The blade 4 of the screw is provided with a guide 8, which is fixed in the groove of the axis 9. The cylindrical part of the copy bolt 7 is provided with a cylindrical sleeve 10 from a material with a low coefficient of friction, which during operation and interacts with the side surfaces of the slot 6. The guide 8 has the ability to move longitudinally in the groove 9 to coordinate the position of all the rotor blades flax the hub 1 and be fixed in the groove with a screw 11. The end face 12 of the guide 8 is open for the guide to enter the groove 9 when replacing a damaged blade 4 with a new one.

Rowing screw self-adjusting step works as follows.

When the propeller of the self-adjusting step is in the starting - accelerating - cruising - braking modes, the braking of the rotor blades 4 is set to the most optimal position, moving along the spiral slot 6 along which the copier bolt 7 slides. At each moment of time, the rotor blade 4 is in position at which ensures the balance of the forces of the centrifugal and lifting forces of the blades, including the balancing force of the blades on the vane section, while the engine speed is automatically set to the most advantageous mode. For additional adjustment, the blades 4 of the screw through the guide 8 are installed in the desired position in the groove 9 and fixed by the screw 11. The bushings 3 provide increased sliding of the axles 5 in the mounting hole 2, and the sleeve 10 provides increased sliding of the copier 7 in the through slot 6, providing thus, the impossibility of “biting” the blades 4 and axis 5 of the screw relative to the hub 1. Replacing the damaged blade is done by removing the damaged blade from the groove 9 and installing a new blade in it, which is done without removing and disassembling the screw.

Claims (9)

1. A propeller of a self-adjusting step, comprising a hub with a copier bolt and mounting holes, in which the axis of the screw blades are made, made with spiral splines, characterized in that the mounting holes are provided with bushings, the spiral slot is made through, and the screw blades are connected with split axles connections. 2. The propeller according to claim 1, characterized in that the axis of the blades are connected to the blades by a detachable connection. 3. The propeller according to claim 2, characterized in that the detachable connection is made in the form of a guide located on the lower part of the blade, which is fixed in the groove of the axis. 4. A rowing screw according to claim 3, characterized in that one of the ends of the guide is open for the guide to enter the groove of the axis of the blade. 5. The propeller according to claim 3, characterized in that the connection of the guide vane in the axis groove is fixed by a screw. 6. A propeller according to claim 1, characterized in that the axis of the blades are installed in the mounting holes of the hub of the screw through the bushings forming friction pairs. 7. A propeller according to claim 6, characterized in that the bushings are made of a material with a low coefficient of friction and having anti-corrosion properties. 8. A propeller according to claim 1, characterized in that the copier bolt interacts with the side surfaces of the slot of the spiral axis of the blade through a cylindrical sleeve. 9. A propeller according to claim 8, characterized in that the cylindrical sleeve is made of a material with a low coefficient of friction and having anti-corrosion properties.