SU47088A1 - Device for checking the displacement of the axes of two interlockable shafts - Google Patents

Description

The present invention relates to a device for checking the displacement of the axes of two interlockable shafts and, as already known devices of this kind, consists of two brackets worn separately on the end of each shaft (there may also be horseshoe magnets) with a driver rigidly fixed on one of the brackets the decree, mounted on the second bracket and consisting of two arrows, each of which gives indications of the corresponding displacement of the shaft in the horizontal and vertical plane.

In this proposal, the pointing mechanism consists of one arrow-pointer, simultaneously moving in a vertical plane and rotating around an axis, for which purpose it is reinforced between the ends of springs mounted on the ends of two spring arms, which are driven by a fork rod moved by the driver.

In FIG. 1, 2, 3, and 3 depict the various positions of the interlocking shafts; FIG. 4 shows a general view of a pointing mechanism with a bracket (magnet) attached to a shaft; FIG. 5 and 5 depict a general view of the driver attached to the end of the second shaft, and FIG. b - promising

view of the device for fastening the pointer.

The proposed device is based on the well-known property of skewed and shifted shafts to change the split between two points of the coupling half; This is illustrated in FIG. 1 and 2; if there is an angle between the shafts, when the shafts rotate, the distance x (Fig. 1) changes, and if there is a shift, the distance y (Fig. 2); if the point T1 of the intersection of the axes of the shafts K (Fig. 3) lies to the right or to the left of the coupling, then when the shafts rotate, the distance x and V also change (Fig. 3).

The device device is based on this. The base of the device is a horseshoe magnet M, the front half of which in FIG. 4 removed; the magnet has Y stops made from a non-magnetic material that facilitate the installation and shooting of the magneto from the surface of the coupling; The frame C is attached to the magnet to which two lamellar springs B are attached at points D to which are attached in the middle of a forked cable ha, which has protrusions at the end for communication with the drive A. The left spring B at the free end has a cutout with a fork and the right has a protrusion entering the plug of the end of the first spring (Fig. 6). The folded up free ends of the spring B are attached with their paws.

U-shaped spring E, on the middle part of which the axis // is fastened and fastened with a nut, bearing the arrow I; at the point L, as in the center of gravity of the whole system, the end of the counterweight lever T is hinged, which relieves the springs even of its own weight and thereby eliminates false readings of the device when it is turned upside down. Behind the arrow is placed a scale fixed to the frame (shown in Fig. 4 by the dotted line), the lines of the zero position of the arrow and the angular divisions are plotted; This device is installed with a magnet on one half of the coupling (for example, on the right), on the left half the actuator shown in FIG. 5 and 5. It has a two-plane horseshoe magnet / 7 for mounting on the top and side of the coupling; A plug C is fastened to the magnet, to which a ring with spring ears W is attached in any position with two clips; these ears are captured by the protrusions of the fork fork g; the device of the ears and protrusions is shown in FIG. 5, from which it is clear that the grip is hinged and at the same time rigid enough.

To use the device, it must be installed on the half of the coupling of the shaft, which is considered to be fixed; on the other half of the clutch install the drive and grab the ledge And the device. From FIG. 1 that when the shafts rotate together, when the shafts are at an angle, the distance x will decrease when the point is inside the angle and increase when the point is on the opposite side. A decrease in distance .x will correspond to the movement of point A of the device (Fig. 4) to the right, if the device is on the right half of the coupling. With such a movement, the forks will tend to turn around some axis and at the same time lift the end of the right spring B and lower the end of the left spring B. Then the right foot of the spring E will lower and the left one will rise, which will turn the axis and the arrow H in a clockwise direction ; with further rotation of the shafts, the distance (fig. 1) will increase, and will be greatest after 180, i.e. below. The instrument rotates together.

with the shafts and with increasing distance, it will definitely move to the left, which is why the arrow will turn counterclockwise; after 90 it will come to the zero position, and when the device is at the bottom, the arrow will turn in the opposite direction and will again indicate the position of the shaft on which the drive is installed, and the zero position line will show the position of the shaft on which the device is installed. Thus, an instrument with a line of zero position clearly shows the position of the shafts in the plane of the instrument and in its changes always follows the shafts.

When there is a shift of the shafts (Fig. 2), the distance y is changed, and the point A of the device receives vertical movements. The fork t ha D lowers or lifts the free ends of the springs B at the same time, which causes the spring E, which means that the axis H and the arrow H in parallel move up or down, giving a complete picture of the shaft shift, the magnitude of the shift and direction. It will be somewhat more complicated when the intersection point of the axes of the shafts lies not in the center of the coupling (Fig. 3) or when there is both a shift of the shafts and an angle between them — in both cases the values x and y will change simultaneously. They differ on the device as follows: when there is no shift of the shafts, then the greatest angle of the arrow corresponds to the greatest deviation of the axis of the arrow from the zero line. position, and the point of intersection of the arrow with the zero line will show approximately the point of intersection of the axes.

The subject matter of the invention.

1. A device for checking the displacement of the axes of two interlocking shafts, consisting of two brackets mounted separately on each of the rollers with a driver rigidly fixed on one of the brackets and acting on the indicating mechanism mounted on the second bracket, characterized in that the cylindrical axis I the pointer is arranged so that it can simultaneously move in a vertical plane and rotate, for which purpose it is reinforced between the ends of the springs E mounted on the ends of two springs I under the action of a fork fork. moved by driver Sh.

2. The form of execution of the device

According to claim 1, characterized in that Vilcha- | shafts.

This cable is equipped with a lever with a counterweight T in order to compensate for the instrument readings when turning

srig, 1

Srig. S

CfDwr. C. ilN. ., W, V