NO133633B - - Google Patents

Description

This invention relates to a fastening device for ladder elements or the like, the free ends of which are tubular and which can be anchored in blind holes in a brick wall by means of sleeves which are provided with internal bores and whose outer surface is provided with peripheral ribs which are designed like barbs and slope towards the direction of insertion of the sleeve .

Such ladder elements, such as ladder stirrups, ladder stirrups, holding stirrups and the like, which are suitably coated with a plastic or with aluminium, are used in sewer shafts, water basins, treatment facilities which are exposed to various chemicals, moisture, steam and the like, and serve to provide access to the interior of such objects.

Up until now, anchoring of ladder elements has most often been carried out by cementing or walling. It is then necessary to have fairly large recesses in the masonry, so that this is weakened at the same time that cracks can occur, through which ground water can penetrate, e.g. in a shaft. This placement and fixing of ladder elements is associated with large material consumption and significant costs. Furthermore, there is a great risk of oxidation and rusting through when the ends of the ladder element are bricked in, so that breaks in the ladder element often occur unexpectedly. The exchange of such anchored ladder elements is also time-consuming and expensive.

One has therefore already proposed, see Swiss p.s. 496 874, to use a fastening device which is designed as a sleeve with barb-like ring ribs arranged on the outside. The end of the ladder element, which is to be anchored, is then inserted into these sleeves which are arranged in a recess in the masonry which is dimensioned accordingly. The barbed ring ribs rest against the inner surface of the wall recess or hole and ensure a

little hold for the sleeve.

Since blind bores in a wall, in which a sleeve of the present type is to be inserted, never have the ideal rounding and in addition have a rather rough wall surface, it has been shown that with the known sleeves no absolutely liquid-tight anchoring can be achieved of the ladder element. It has also been shown that as a result of certain protruding places in the borehole, such as due to particularly hard rock particles, such strong deformations of the ring ribs can occur that water can seep out. In addition, it can happen that the ring ribs are damaged due to such protrusions formed by stone residues, which can also cause leaks.

The purpose of the invention is to provide an improved holding device for a ladder element which largely ensures a liquid-tight anchoring in the masonry, and this is achieved according to the invention by the circumferential ribs being divided into shell-like sections and the breaking points between adjacent circumferential ribs being mutually offset in the circumferential direction.

As the circumferential ribs are divided into sections, a Jiedre ttlpasyiiJig of the fastening device to the wall of the bore is achieved and thereby a better seal. In addition to this, the individual sections will more easily "catch themselves" in the wall of the bore than is the case with continuous circumferential ribs, so that the fastening is the best possible. Any chunks of loose rock in the borehole will find their place in the sleeve and will be unable to cause leaks. Damage to the circumferential ribs during insertion of the sleeve will practically be excluded, as the individual sections will be much more elastic than continuous circumferential ribs.

Preferably, the sleeve's surface is also designed with longitudinal ribs, whereby they will be prevented from rotating in the bore.

The invention shall be explained in more detail by means of an embodiment with reference to the drawings, whose fig. 1 shows part of a shaft with ladder elements, fig. 2 shows an axial section of a fastening device according to the invention, fig. 3 and 4 show the inner surface of a sleeve in the unfolded state in two variants and fig. 5 shows in perspective a sleeve according to the invention.

By ladder element here is meant a U-shaped bent hoop made of steel, light metal or other suitable material, further ladders composed of individual elements or made in one piece, associated means of entry or access, such as handles, guardrails and the like.

Fig. 1 shows a partially assembled ladder device for giving access to the interior of a sewer shaft. The ladder device consists of a number of U-shaped pipe sections 19 which are provided with a cover and which are fixed above each other in the wall 1 of the shaft.

For this purpose, a hole 2 is drilled in the shaft wall, the diameter of which is somewhat smaller than the largest diameter of the sleeves 3 that are to be inserted into the holes. Such a sleeve 3 is shown in axial section in fig. 2. The sleeve consists of a hard plastic and is made with a round or square bore 4, the inner surface of which is designed with ring-shaped ribs or elevations 5 which are interrupted in the circumferential direction, so that shell-like sections with intermediate break points are formed. The outer surface of the sleeve 3 is also shaped with annular ribs 6 which are likewise broken to form sector-shaped, shell-like sections 7 with fracture points 8. These sections 7 of the annular ribs 6 are of different sizes and have an inclined surface deviating from the cylinder surface, the slope of which is directed towards the sleeve's 3 insertion direction P. The surface of the inner ribs 5, on the other hand, is oriented in the insertion direction P. The fracture sites 8 between the individual shell-like sections are distributed in such a way that the fractures 8 in adjacent annular ribs 6 are offset from each other in the circumferential direction so that there are never two neighboring fracture sites that are flush with each other in the axial direction. In this way, a labyrinth seal is achieved which prevents moisture from seeping into the sewer shaft. Furthermore, the sleeve 3 is provided with longitudinal ribs 18 (fig. 5) which secure the sleeve against turning in the hole.

The sleeve is driven into the hole 2 in the direction of the arrow P. The individual shell-like sections 7 then spring against the inner wall and secure the sleeve in the hole 2, so that extraction of the sleeve is completely prevented. Even if the hole wall is uneven or the hole is not completely round, the scale-like sections 7 adapt to the adjacent wall surface portions and seal against the hole wall.

In the embodiment according to fig. 4, the outer ribs are arranged helically and, as above, divided into individual shell-like sections 9. Also in this case, the fracture points 19 in adjacent screw turns are offset from each other in the circumferential direction, so that a labyrinth seal is formed. The slope of the

the surface of the helically arranged ribs is directed towards the

sense insertion direction P.

The design and arrangement of the inner ribs 5 are precisely

tig as for the outer ribs, except for the slope of the ribs over the battens, which is corrected in the introduction of the seal.

After the sleeves 3 have been inserted into the holes 2, and the simple

te rib section. 7 respectively 9 has assumed its position, the legs 11 of the ladder elements 19 are pressed into the sleeves 3. The diameter of the legs 11 is somewhat larger than corresponding to the bore 4 of the sleeves 3, so that the sleeve

the tendon is somewhat expanded and closes the largest part of the fractures 8

respectively 10. The formation of labyrinths represents a further security against moisture passing through any openings. The ladder element 19 will be immovably held and the longitudinal ribs 18 which are shown in the embodiment according to fig. 5 will prevent any turning of the sleeve 3 in the bore 2.

As mentioned, fig. 1 a partially assembled ladder device-

ning with three pre-assembled, anchored ladder elements 19 for entry into a sewerage shaft. In the same way, the differently designed ladder elements, such as a rod-shaped auxiliary handle 21 which is provided with a sleeve 20, can be attached to the wall. The auxiliary grip 21 is displaceable in the sleeve 20 and can be brought to the rest position shown in dashed lines after use.

Should it be necessary for any reason to

remove a ladder element from the wall, the anchoring can be loosened using a hydraulic jack that is placed between the ladder element

tets 19 intermediate piece and the wall.

Claims (4)

1. Fastening device for ladder elements or similar, if free ends are tubular and which can be anchored in blind holes in a brick wall by means of sleeves which are provided with internal bores and whose outer surface is provided with peripheral ribs which are designed like barbs and slope towards the insertion direction of the sleeve, characterized by the fact that the peripheral ribs (6) are divided into scale-like sections (7 and 9) and the breaks (8 and 10) between adjacent circumferential ribs (6) are offset from each other in the circumferential direction. 2. Fastening device according to claim 1, characterized in that the outer surface of the sleeve (3) is also designed with longitudinal ribs (181. 3. Fastening device according to claim 1 or 2, characterized in that the circumferential ribs (6) are designed as parallel ring ribs. 4. Fastening device according to claims 1 or 2, characterized in that the circumferential ribs (6) run in a helical shape.