SU540181A1 - Stand for static balancing of propellers - Google Patents

Description

one

This invention relates to shipbuilding and ship repair and can be used in static balancing of propellers.

A stand for static balancing of propellers, containing two parallel supporting knives, a mandrel with centering cones for mounting a balancing screw, which is mounted on supporting knives 1, is known. In this stand the mandrel is horizontal.

The disadvantages of the known stand for large-sized propellers are the cumbersome, increased complexity of screw assembly with centering mandrel, as well as low balancing accuracy due to insufficient alignment accuracy when assembling the geometric axes of boring of the propeller hub and centering mandrel.

Also known is a stand for static balancing of propellers, containing a base plate, mounted vertically on a base plate, a balancing spindle, having in the upper part a bench, a hollow centering spindle, having in the upper part a pile supported on the pad, a lifting table and a centering mechanism, placed on the centering pin, unloading mechanism placed on the base plate and unbalance measuring mechanism 2.

In this stand, the centering mechanism is made in the form of an eccentric block consisting of an average disk and two eccentrics mounted on it above and below, which are clasped by disc arms, on the upper yoke there are four supports for installing the propeller. The screw is centered on this stand by rotating the upper yoke and the middle disk relative to each other, shifting the screw and adjusting its position.

This stand has an insufficient accuracy of alignment due to the lack of means to control the correct position of the axis of the propeller

and greater complexity of balancing.

The aim of the invention is to reduce the labor intensity and increase the accuracy of balancing. This is achieved by the fact that the centering mechanism is made in the form of an aerostatic plate with annular seals placed on the supporting surface of the lifting table, and a cross with retractable locking pins mounted on the centering spindle. The stand is equipped with levers that are hinged with a lifting table and with an aerostatic washer, and balancing weights placed on the levers. The drawing depicted en opposed stand,

vertical section.

A balancing spindle 1 with a flat bolster 2 is rigidly connected with a supporting plate 3 mounted on the foundation 4. On the base plate 3 there is a unloading mechanism made in the form of, for example, a ring hydraulic jack 5. On the piston 6 of the jack there is a movable holder 7, an external the support cone of which can contact (in the raised position) with the conical surface of the lifting table 8, mounted on the centering spindle 9. To the upper part of the centering spindle 9 coaxially 10 is attached coaxially with the spherical bearing I. Mechanism The centering of the propeller 12 includes a removable pre-centering cone 13 worn on the centering spindle 9 and in contact with the flat bearing surface of the lifting table 8 aerostatic washer 14 with o-rings 15 and a closed cavity 16, and a cross-piece 17 with sliding fingers 18 fixed by nuts 19. A threaded nut 20 is screwed onto the threaded part of the trunnion 10. The lifting table 8 and the aerostatic washer 14 are respectively connected with levers 23 by means of swivels 21 and hinge links 22, respectively. Shiva weights unbalance measuring mechanism 24. Situated on the hub 8 and the lifting table comprises a rotatable rod 25 with balancing weights 2 and the swivel bracket 27 with two mutually perpendicular, e.g., squared, levels of 28.

The device works as follows.

In the jack 5 serves under the pressure of oil, for example, from a hand pump. "

The piston 6 of the jack 5 through the yoke 7 and the lifting table 8 acts on the centering spindle 9 and lifts the spherical support AND over the flat plate 2, unloading the balancing spindle 1. Put the interchangeable cone 13 of the preliminary centering on the centering spindle 9 and place the aerostatic washer 14 in the center of the lifting spindle 9 table 8. Propeller 12 set the crane on the aerostatic washer 14 large hole in the hub up. The interchangeable cone 13 in this case roughly centers the propeller 12 about the axis of the centering pin 9 (with an accuracy of 2-3 mm). After the compressed air is supplied to the cavity 16 of the aerostatic washer 14, a lift force occurs, balancing the mass of the propeller 12. As a result, the aerostatic washer 14 with the propeller 12 acquires the ability to move easily along the plane of the lifting table 8 with very small forces applied. Retractable fixed fingers 18 crosses 17, previously installed at a certain radial size, interact with the conical surface of the hole in the hub of the propeller, almost instantly and with high accuracy center the propeller 12, i.e., align the axis of its hub with the axis of the centering spindle 9.

The cross 17 onus can be either under the action of its own weight, or when it is pressed on the nut 20. When the centering wheel moves 14, the imbalance of its mass is automatically compensated by the restoring moment that occurs when the balance weight 24 is moved to the opposite side on two shoulder arms 23.

After the alignment of the propeller 12 is completed, the compressed air supply is stopped, the piston 6 of the jack 5 together with the yoke 7 is lowered, and the centering spindle 9 with the spherical support 11 sits on a flat bow 2. Under the action of the unbalanced mass of the propeller, the centering spindle 9 rotates at an angle the location and magnitude of which characterize the plane of the location of the unbalanced mass and the magnitude of the moment it creates. These parameters are determined with the help of a pivoting arm 27 with levels 28 and a pivot rod 25 with weights 26. The propeller is processed to imbalance in a position where the spherical support 10 is raised above the flat bollard 2.

The proposed design of the stand reduces the complexity of the balancing process due to the mechanization of the centering process, regardless of the size and weight of the balanced propeller and improving the accuracy of the balancing process by pre-setting the centering mechanism with any predetermined degree of accuracy.

Claims (2)

1. A stand for static balancing of the propellers, containing a base plate, mounted vertically on a base plate, a balancing pin, having a bottom plate in the upper part, a hollow centering spindle, having a pin supported on the pad, a lifting table and a centering mechanism in the top part, placed on the centering spindle, an unloading mechanism located on the base plate, and an imbalance measurement mechanism, characterized in that, in order to reduce labor intensity and improve the accuracy of balancing, the centering mechanism is made an aerostatic washers having annular sealing and placed on a supporting surface -podemnogo section and crosspiece with sliding locking fingers mounted on centering spindle. 2. A stand according to claim 1, characterized in that it is provided with levers hingedly connected to a lifting table and an aerostatic washer, and balancing weights placed on the levers. Sources of information taken into account in the examination: