SU95751A1 - Foldable tower - Google Patents

Description

Known telescopic sliding columns of the tower, made, for example, from solid pipes, are complicated and cumbersome.

A significant disadvantage of towers with a telescopically extending column is the fact that, due to the flaws between the guiding parts of the column sections, the latter receives a pronounced one-sided curvature of its axis.

The telescopically extending column of the tower has a square cross-section with the use of intermediate lifting cables that connect the sections of the column in series and slice through the blocks mounted on the sections. A feature of the proposed construction of the tower is that the blocks that carry the prol ejector lifting cables are located parallel to one of the diagonal planes of the column and are shifted from this plane alternately in one direction and the other. This feature causes the zigzag-like curvature of the axis of the column due to the gaps between its sections, reducing the bending moments in it, and consequently, the ability to build folding towers with telescopically sliding colony of natural height without excessively loosening the structure.

FIG. 1 is a schematic view of a tower tower, side view; in fig. 2- indications (conditionally) of the column deformation; in fig. 3 shows the arrangement of blocks of wire cables between the two lower sections in axonometry; in fig. 4 - joint of two sections, side view and in plan.

The welded telescopic column for the collapsible mobile rigging consists of and; .1tp sections. All sections of the column, except the top, are made in the form of a through-welded square cross-sectional section of angular iron with bars of the slats. Upper section

No. 95751-2 -

It is made from because its transverse dimensions are small.

HaBeps fl-e.iftlKcftfi-iecKofi columns reinforced the platform (Kopsi-iHaj, in which the worker rises with the necessary tools and materials.

Intermediate lifting cables / each connected to the top HQMV end of one section, thrown over the blocks 2, mounted on the upper end of the next height section and attached to the lower end of the third height section. Since the cables / pairs are located on both sides of each section, they can be combined into one cable, retracted through two blocks 2 and another through block 3, mounted on the lower end of the third section.

Blocks 2 and 3 are arranged parallel to one of the diagonal planes of the column with an offset (with eccentricity) alternately in one and the other direction.

The entire column is lifted by a winch 4 (Fig. 3) mounted on the bottom of the column itself. The cable 5 from the winch is passed through a system of blocks 6, 7, 8, 9, 10 and 11, fixed in Fig. M. 2 and 3 in order on the bottom of the 1st and next sections. Such a system of blocks required an increase in the load on the lower section and the need to maintain an eccentric force of forces relative to the corresponding diagonal plane when the winch drum is located parallel to one of the edges of the coloia. The latter is necessary in connection with the convenient placement of the winch between the support yogas of the lemma in the folded condition.

To reduce friction, each square section has four rollers 12 (FIG. 4) fixed on the lower part of the section. These rollers are but internal regiments, coal coal of the next large sections. Four pairs of rollers 13 are reinforced in the upper part of the section, on which the outer sides of the squares of the smaller, smaller sections of the column section abut.

The upper section is moved in sleeves reinforced in the upper part of the second (above) colo1.

In the course of work, the worker is moved along the upper platform (in the basket), creating his own bending moment per column by his own weight. Lifting cables located eccentrically relative to the diagonal axis of the cross section of the column, create an eccentric effort, and therefore, tilting moments relative to this axis.

By choosing the value of the exceitricity of the fastening of the blocks relative to the diagonal plane of the column, it is possible to regulate the magnitude of the moment tilting the coloi section.

If the magnitudes of the moments generated by the cables are greater than the moments created by the workload, then when the latter is moved inside the basket, the column sections in the joints will not be rearranged and, therefore, column oscillations are excluded.

Adjusting the magnitude of moments that bend sections of a column by choosing shoulders also allows you to SMARGE the actually acting voltages in the column sections and, therefore, to create stability of the telescopic colony with minimal weight.

The location of support points for sections a, b, and c in the shakhmatiy order allows alternate tilting of sections, does not distort the colo axis in ONE side, as is the case in lime columns.

Since the sections are displaced one relative to another and the gap size between the two sections will occur in the direction of a diagonal column, the gap in the upstream diagonal plane will be eliminated and, consequently, the column will be rigid in the direction of this second plane.

The base of the tower, not shown in the drawing, is made of swivel folding legs. The column can rotate about a horizontal axis on the base when the tower moves from place to place and during storage.

Subject invention

Folding tower for finishing, repair and other works, having a telescopically sliding column of square cross section using intermediate lifting cables, sequentially connecting the young sections of the column and throwing them through the blocks mounted sections to the other, characterized by the fact that the blocks carrying intermediate lifting cables , are located parallel to one of the diagonal planes of the column and are shifted from this plane alternately in o / yoke and in the other direction, in order to exclude a one-sided curvature of the axis of the column and mei There are a lot of exciting moments in it.

No. 95751