RU1105095C - Device for radial adjustment - Google Patents

Description

FIELD OF THE INVENTION The invention relates to crosslinking and is an improvement-L; crv: 1 Vm device according to Auth. St. NJ 843307. ,,

The main invention, Sat, 1, holds a body, an arm and two cylindrical szcentrics mounted for rotation and fixing in the holes of one of the mentioned parts and placed in the holes of the other part, one of the holes for accommodating the eccentric is oval and the axis of the holes housing and bracket in each of the parts are located in the same plane.

A disadvantage of the main device is the low accuracy of tuning of the focusing system near the center of the control zone. Due to technological tolerances, blind spots are possible near the center of control zone B, i.e. the inability to set the axis of the focusing lens to the center of adjustment for any combination of cam positions.

An object of the invention is to improve alignment accuracy near the center of the control zone.

The goal is achieved in that in the main device the axis of the focusing system is spaced apart from the plane of the axes of the housing openings at a distance greater than the eccentricity of the cylindrical eccentrics; SE.

In FIG. 1 shows the proposed device; figure 2 is a section aa in figure 1; Fig. 3 is a graphical diagram of the zones of the CO control or the axes of the focusing system: C - the main; 36 - the proposed device; on the

Fig. 4 is an image of the adjustment zones of the focusing system: 4a - the main, 46 device of the proposed device.

The device for radial alignment comprises a housing 1, an arm 2, cylindrical eccentrics 3 and 4, mounted with

He spoke about the possibility of rotation in the holes 5 and 6 of the bracket 2. In the housing, one hole 7 for accommodating the eccentric is made round and the other 8 is oval. The axes of the holes in each part lie in one

ate the plane. A focusing system 9, the axis 10 of which is rigidly fixed in the housing

spaced from the plane passing through the axes

holes 7 and 8, at a distance greater than the eccentricity of eccentrics 3 and 4.

The alignment of the axis 10 is carried out by rotating the eccentrics 3 and 4 with respect to the fixed axes of the holes 5 and 6. The regulation zone of the axis 10 in the radial direction is determined by the eccentricity of the two pairs of holes 5 and 7, b and 8, as well as the location of the axis 10 relative to the holes 7 and 8.

In the proposed device, as well as basically, the control zone has three sections (see Fig. 4). In the first and second sections formed by the curved shapes LmMlL and KkNmK, the position of the axis 10 is determined by one position of the eccentrics. In the third section formed by the curved shape LIMNkKL, the alignment of the position of the axis 10 is determined by two different positions of the eccentrics. From a comparison of the control zones of the main and the proposed devices, it follows that for the main with the smallest technological tolerances, blind zones near point B are possible. In the proposed device, the appearance of blind zones is possible only in

In the event that the technological tolerances are distorted by the LIM and KkN curves so that the latter come into contact. Minimum distance between LiM curves

and KkN increases with increasing distance from the axis 10 to the plane passing through the axis of the holes 7 and 8. Therefore, by choosing this distance greater than the eccentricity of the eccentrics 3 and 4, with any technological tolerances, it is possible to ensure that there are no blind spots,

Thus, the location of the axis of the focusing system at a distance from the plane of the axes of the housing openings, greater than the eccentricity of the eccentrics, increases the alignment accuracy near the control center.

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