RU2796336C1 - Telescopic stand for load lifting device - Google Patents

Abstract

FIELD: lifting devices.

SUBSTANCE: telescopic strut (T), in particular for a load lifting device, consists of an outer tube (AR) and an inner tube (IR) guided through it. The inner tube (IR) can be displaced in the outer tube (AR) in the longitudinal direction. A number of bearings (G) are installed on the outer pipe (AR) to guide the inner pipe (IR). The sliders (G) are inserted from the outside each into one hole in the wall of the outer tube (AR) and protrude inward to guide the inner tube (IR).

EFFECT: simplification of design and maintenance is achieved.

10 cl, 5 dwg

Description

The invention relates to a telescopic post according to the restrictive part of claim 1 of the claims.

Telescopic struts (shortly: telescopes) are often used to stabilize the structural units of lifting and lowering equipment for lifting and lowering loads (so-called lifting mechanisms or "suspensions"). Here, the inner tube, which is shifted in the outer tube, is drawn in or out during the lifting or lowering movement.

Publication DE 10 2004 045 516 A1 - Assmann, "Device for lifting and stabilizing loads", shows such telescopic struts for stabilization in a device for lifting loads.

IT MO 20120019A1 - Cosben "Braccio Telescopico" shows an outer telescopic boom section of a crane having integral guide elements on the outer tube, which have a screw-based adjusting device between the bearing and the upper part.

Also WO 2014/191561 A1 and EP 1 982 948 A2 show telescopic crane sections having this design.

FR 2 759 687 A1 shows guide elements inserted from the end into the outer section of a telescopic crane arm.

Until now, telescopes that are used to stabilize the structural components of handling equipment are made with guide rollers. In this case, the displacement of the inner tube in the outer tube is carried out on several, partially adjustable guide rollers. Moreover, these guide rollers are located, for example, horizontally and vertically on the outer tube of the telescope and serve to guide the inner tube. Each guide roller is rotatably supported in roller bearings, which, in turn, are welded to the outer tube. In this case, the roller bearing should facilitate movement with as little friction as possible and at the same time guide the inner tube in the outer tube with the smallest possible clearance. This solution with rollers and integrated bearings (eg ball bearings) is technologically laborious and therefore expensive. In addition, the replacement of the rollers in the event of a defect or, accordingly, in the event of damage due to wear, is time-consuming and therefore leads to long downtimes for said lifting mechanisms. In addition, also the adjustment of the guide gap of the telescopic struts is time-consuming in the said roller-based solution.

It is therefore an object of the present invention to provide a simple, functional and low maintenance design for such telescopic poles.

The main idea of the solution of this problem proposed by the invention is to create a guide for the inner tube in the outer tube of the telescopic strut using easy-to-manufacture sliders. These sliders, for easy external mounting, are inserted into the corresponding holes in the outer tube and guide the inner tube. They are preferably made from a material having good sliding properties, for example a polymeric material.

The problem is solved, in particular, using a telescopic rack according to claim 1 of the claims.

It proposes a telescopic strut suitable for a stabilizing device for a load lifting device, in particular for suspension for vehicles or parts of vehicles, and this telescopic strut consists of an outer tube and an inner tube guided in it, while the inner tube is guided in the outer pipe with the possibility of displacement in the longitudinal direction. At the same time, a number of sliders are installed on the outer pipe to guide the inner pipe, and these sliders are each introduced from the outside into one hole in the wall of the outer pipe and protrude inward to guide the inner pipe. This solution is simple in design and cost effective to manufacture, has good sliding properties, small lead clearance and is easy to set up and maintain.

Preferred embodiments of the telescopic strut according to the invention are indicated in the dependent claims.

The features described here and their advantages can be realized both individually and in expedient combination with each other.

Preferably, the inner tube is made of a metallic material and the bearings are made essentially of a polymeric material. Bearings made of polymeric material have good running properties and a low degree of wear on metal surfaces.

A small telescope skew clearance is obtained when the bearings are grouped in two spaced regions (guide regions) of the outer tube, and at least four bearings are located in each of these regions, annularly distributed around the perimeter of the outer tube.

In a particularly preferred embodiment, the outer tube and the inner tube each have a substantially rectangular cross-section, with two sliders located next to each other in each of the areas on the wide sides of the outer tube, and one slider located on the narrow sides. .

Preferably, the bearings, at least in the shear direction, have a chamfer at the contact surface with the inner tube. This not only improves driving properties, but also makes it easier to assemble the outer tube complete with bearings with the inner tube, for example after disassembly.

According to the invention, the bearings have an essentially T-shaped cross-section, wherein the narrow part of the bearing is drawn from the outside through the opening of the outer tube, while the protruding, wider part of the bearing, as a supporting surface, rests on the outside at the edge of the opening against the outer tube and in the area this support surface is connected to the outer pipe, preferably screwed. The bearings can therefore be mounted or replaced at any time, even when the inner tube is already pushed into the outer tube. In addition, the guide gap can be adjusted from the outside. To do this, preferably between the outer side of the outer tube and the bearing surface of the bearing is inserted along the spacer, while, depending on the thickness or number of spacers, the bearing protrudes more or less deeply into the inner cross-section of the outer tube and can thus be precisely adapted to the dimensions (for example, width) of the inner tube. In this case, in one of the preferred embodiments, the spacer can be replaced in order to adjust the guide gap of the telescopic strut and/or to compensate for the wear of the side bearing G. Alternatively, adjusting screws, in particular countersunk screws, can be provided in the additional threaded holes of the side bearings in the support area to adjust the penetration depth.

Preferably, a steel sheet or a plastic plate is provided as a spacer, which in one of the preferred embodiments is pushed laterally under the bearing surface of the side bearing. Preferably, the spacer is screwed to the slider and the outer tube, in one particularly preferred embodiment, the same screws both fasten the slider to the wall of the outer tube and fix the spacer (intermediate plate, "gasket"). For this purpose, preferably, the spacer and the side bearing have identical drillings or, respectively, a matching pattern of holes, the screws used to fasten the side to the outer tube are passed through the holes of the spacer. In one variant, the spacer does not have drillings, but U-shaped screw cutouts that are open towards the outer edge, so that the spacer, even with the screws already mounted, can be pushed laterally under the supporting surface of the loosened side bearing. The spacer is then preferably clamped between the bearing surface of the bearing and the outer tube for fixation.

One of the embodiments of the telescopic rack according to the invention is explained below with the help of the drawing.

This shows:

figure 1: a sectional view of the telescopic rack according to the invention;

figure 2: two views in perspective (bottom side, top side) of the telescopic rack;

figure 3: local view of the area, including three bearings;

figure 4: cross-sectional view of the outer tube, together with mounted bearings;

figure 5: cross-sectional view of the outer tube with mounted bearings and the inner tube.

Figure 1 shows a detailed cross-sectional view of the telescopic column T ("telescope") according to the invention, having an outer tube AR and an inner tube IR, while in two guide areas FB1, FB2, bearings are located annularly around the outer perimeter of the outer tube AR. The guide areas FB1, FB2 are spaced apart to avoid warping of the inner tube IR in the outer tube AR. But at the same time, both guide areas FB1, FB2 are located so close to the open end of the outer tube AR that even with the inner tube IR almost completely drawn out, it is guided in two guide areas FB1, FB2, and therefore a reliable, skew-free guide is still provided.

Figure 2 shows the telescopic column according to the invention in a perspective view, in one case from the first, upper side, and in the other case from the second, lower side. The reference designations already introduced in FIG. 1 also apply to FIG. 2 and all subsequent figures. In addition to the depiction of FIG. 1, FIG. 2 shows sliders G, which are each fixed from the outside with 6 screws in the wall of the outer tube AR. In contrast to figure 1, in which the inner tube IR in this image is pushed into the outer tube AR from the left side, the inner tube IR in figure 2 is pushed from the right side end of the outer tube AR. Accordingly, in FIG. 2, guide areas FB1, FB2, having bearings G, are located at the right-hand, open end of the outer tube AR.

Fig. 3 shows a partial view of the mounted bearings G near the open end of the outer tube AR. The substantially T-shaped cross-section of the bearings G is thus distinguishable, with the 6 screws that fasten each bearing G being screwed in a protruding area adjacent to the outer tube AR from the outside, and the smaller, cylindrical or rectangular part of each bearing G protrudes through a corresponding opening of the outer tube AR into the interior of the outer tube AR and guides the inner tube IR with its underside. Figure 3 also shows the spacers D (intermediate plates, "spacers"), which, by their thickness, determine the depth of penetration of each bearing G into the inner region of the outer tube AR.

4 shows a cross-sectional view across the longitudinal direction of the outer tube AR in the region of the mounted bearings G. The inner tube is not shown in this picture. It can be seen here that the bearings G are provided with a chamfer F on all sides in the region of their sliding surface. In other embodiments, in which a lubricant is additionally used (preferably based on PTFE (polytetrafluoroethylene)), the sliding surface may also have a texture in the recesses of which the lubricant can adhere.

FIG. 5 also shows a cross-sectional view of the outer tube AR in the region of the six mounted bearings G, in which the inner tube IR is also shown. For bearings G on the narrow sides of the outer tube AR, the drawing shows the guide clearance SP (clearance). It is adjusted by introducing more or less thick spacers D to lay the bearing surfaces of the outer tube AR in the area of the contact surfaces of the bearing G.

Polymer material, in particular based on pure, ultra-high molecular weight low-density polyethylene, in combination with an IR inner tube made of metal, has proven itself as a material for sliders.

The bearings proposed here are easy to manufacture, for example, by machining. By eliminating the need for a roller structure having roller supports, welding-induced buckling of the outer tube during manufacture is reduced. It follows that the outer tube can be produced more precisely and is cheaper to manufacture. The design proposed here allows easy adjustment or, accordingly, adjustment of the bearings, as well as the possibility of a simple replacement.

Claims (17)

1. Telescopic pole (T) for a stabilizing device for a lifting device, in particular for suspension for vehicles or parts of vehicles, moreover, this telescopic strut (T) consists of an outer tube (AR) and an inner tube (IR) directed in it, wherein the inner tube (IR) is movable in the outer tube (AR) in the longitudinal direction, bearings (G) are installed on the outer pipe (AR) to guide the inner pipe (IR), wherein these sliders (G) are each inserted from the outside into one hole in the wall of the outer tube (AR) and protrude inward to guide the inner tube (IR), differing in that that the bearings (G) have an essentially T-shaped cross-section, with the narrow part of the bearing (G) being drawn from the outside through the opening of the outer tube (AR), and moreover, the protruding, wide part of the bearing (G) as a bearing surface rests on the outside against the outer tube (AR) and in the area of this bearing surface is connected to the outer pipe (AR), preferably screwed, and that a spacer (D) is inserted between the outer side of the outer tube (AR) and the bearing surface (G). 2. A telescopic pole (T) according to claim 1, characterized in that the inner tube (IR) consists of a metallic material and the sliders (G) consist essentially of a polymeric material. 3. Telescopic strut according to one of the preceding claims, characterized in that the bearings (G) are grouped in two spaced areas (FB1, FB2) of the outer tube (AR), and in each of these areas, distributed annularly around the perimeter of the outer tube ( AR), at least four of said bearings (G) are located. 4. Telescopic strut (T) according to claim 3, characterized in that the outer tube (AR) and the inner tube (IR) each have a substantially rectangular cross-section, and in each of the areas on the wide sides of the outer tube (AR) next to each other with the other two bearings (G) are located, and on the narrow sides there is one bearing (G) each. 5. Telescopic strut (T) according to one of the preceding claims, characterized in that the sliders (G) at least in the shear direction have a chamfer (F) at the contact surface with the inner tube (IR). 6. Telescopic strut (T) according to one of the preceding claims, characterized in that the spacer (D) is replaceable for adjusting the guide clearance (SP) of the telescopic strut (T) and/or for compensating for bearing wear (G). 7. Telescopic pole (T) according to one of the preceding claims, characterized in that a steel sheet or a polymer plate is provided as a spacer (D). 8. Telescopic strut (T) according to one of the preceding claims, characterized in that the spacer (D) is screwed to the bearing (G) and the outer tube (AR). 9. The telescopic pole (T) according to claim 8, characterized in that the spacer (D) and the slider (G) have matching drillings, and the screws used to fasten the slider to the outer tube (AR) are passed through said spacer (D) holes ). 10. Telescopic pole (T) according to one of the preceding claims, characterized in that the spacer (D) is sandwiched between the bearing surface of the bearing (G) and the outer tube (AR).

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