DE1859206U - EXPANSION PROFILE. - Google Patents

Description

Extension profile The invention relates to a channel-like extension profile for mining, tunneling or the like, especially for the expansion of the line under Days.

When expanding routes, chambers or the like, one uses ring or arcuate expansion frames, which generally consist of several segments. the individual segments are placed one inside the other with their ends and by means of tabs, Brackets or the like braced together. There is the possibility of the connection to be designed in such a way that the expansion frame in the manner of a sliding arch expansion Pushing in the segments can yieldingly evade the pressure. For such expansion frames channel-like or bell-like profiles are known. The profiles become in the same direction placed inside each other, and the segments in the overlap area so braced together, that when a certain load is exceeded they slide into one another in the direction of pressure. The profiles of the inner and outer segments generally have the same profile shape and profile size.

The invention aims at a particularly advantageous profile of this type, in particular a profile whose resistance values in the x and y directions are comparable Weights per meter are larger than similar profiles of this type. It also aims a profile, which a particularly advantageous connection of the nested Segments permitted, taking into account the sinking resistance of the extension frame.

According to the invention, the flange webs are of the channel-like profile in the inside and outside of the profile by hyperbolic curves lying one above the other in the y-direction limited, the asymptote angles being the outer and inner hyperbolic Boundary lines are either the same or different from one another, but preferably the asymptote angle the outer boundary line of the flange webs is smaller than that of the inner Boundary line.

The flange chords of the profile are preferably of this type designed that when bracing two in the Uoerlappungsbereich lying one inside the other Segments by pressing the flange straps against each other the flange webs of the outer Profile towards the inside of the profile resiliently against the flange webs of the inner profile be pressed. For this purpose, the flange straps of the profile can be hook-shaped be bent obliquely downwards, so that the flange straps when the profiles lie one inside the other of the inner profile partially encompass the flange straps of the outer profile and when tensioning the profiles by touching the flange straps, the flange webs be pressed against each other over their full length. It becomes an extra one that way elastic bracing of the segments is achieved, which reduces the sinking resistance of the extension increased significantly.

Such a design of the flange chords is particularly important in such Profiles advantageous in which the asymptote angles of the outer boundary lines are smaller than the asymptote angles of the inner web boundary lines. You get here the profile webs are pressed against one another approximately over the entire length of the Bars, the contact pressure being distributed approximately evenly over the length of the bar.

It can also be useful to move the flange straps upwards to be tapered to a point. As a result, the flange straps can under load of the expansion frame penetrate into the mountains surrounding the frame, creating a solid Connection of the expansion frame to the mountains is achieved and a lateral bending of the frame is prevented in the direction of the route.

The tapering shape of the flange straps thus has an effect as a bolting of the frame.

To increase the sinking resistance of the extension, you can use Lur an im the segments brackets for an inside of the segments arranged tension band are attached, which are taken along when inserting the segments under deformation of the tension band-son these. One end of the tension band can be attached to one of the two brackets and guided around at least 1800 via deformation beads or the like of the other bracket. The brackets are expediently designed as brackets which are easily detachable from the frame and which grip around the flange belts of the outer profile in the shape of a hook.

You can by arranging wedges, screws o. The like. Simultaneously serve to brace the nested segments.

For this purpose, however, additional means of a known type, for example, clamps are provided.

The expansion profile according to the invention has various essentials Advantages. The profile shape, which is easy to roll, has moments of resistance in the x and y directions that are higher than the corresponding values of a similar profile shape. With the same The profile according to the invention accordingly has a lower weight per meter than similar profiles. The possibility of elastic tightening is a particular advantage of the profiles lying one inside the other due to the resilient pressure of the profile webs. The formation of the flange straps connects the expansion frame firmly with the rock and in this way prevents the extension from bending sideways in the direction of the route. The bolting of the individual expansion frames can be omitted or easier are executed.

The drawing shows exemplary embodiments of the invention: FIG. 1 shows an expansion profile according to the invention; Fig. 2 shows two nested in the same direction Profiles according to the invention in the untensioned state; Fig. 3 shows the arrangement according to Fig. 2 in the clamped state; Fig. 4 shows two in the untensioned state nested profiles according to the invention, in which the asymptote angles of the outer land boundary lines are larger than those of the inner land boundary lines.

Fig. 5 shows a connection between two extension segments by means of clips, a drawstring with the clamps in connection to increase the insertion resistance is brought; Fig. 6 shows a section along line V-V of Fig. 4; Fig. 7 shows a section along line VI-VI of FIG. 4.

The channel-like profile of FIG. 1 has a reinforced profile arch 1, two flange webs 2 and upper flange straps 3. The profile base 1 is on the inside and bounded on the outside by circular curves, while the flange webs 2 on their inner Areas 4 and 5 on their outer surfaces are bounded by hyperbolic curves. the Circular curves of the profile base run towards the profile webs in the hyperbola curves above. The zero point of the hyperbola curves is therefore to the side of the y-axis.

The asymptotes on the hyperbolic curves are labeled 6 and 7, respectively. According to the selected embodiment, the Ãsymptotenwinkelo (the asymptote 6 of the inner boundary line 4 larger than the angle; 8 the asymptote 7 the outer Boundary line 5. The flange straps 3 are drawn downwards at an angle in the shape of a hook. The flange belts 3 taper towards the top.

In FIG. 2, two profiles according to FIG. 1, that is to say with different asymptote angles ole and β, are placed one inside the other, without to be tense with one another, however. As Fig. 2 shows, remain between the profile floors 1, the flange webs 2 and the upper flange straps 3 columns 8,9 and Ao free; the profiles therefore only touch on the lower part of the flange webs 2.

FIG. 3 shows the arrangement according to FIG. 2, but with the profiles are pressed into one another by suitable clamping means.

The flange webs 2 of the profiles are now elastically pressed against one another. The design of the flange straps creates additional bracing of the profile is achieved because the inner profile exerts the tensioning forces via the flange straps 3 in the direction of arrows A on the flange belts 3 of the outer Profiles transfers, whereby the flange webs 2 of the outer profile inwardly against the Flange webs of the inner profile are pressed. This makes the gap open of the profile increased. If the inner and outer boundary lines 4,5 of the flange webs have the same asymptote angle, the flange webs 2 are except on the profile bottom 1 and the flange straps 3 in the untensioned state of the profile in close contact. But here, too, results from the transmission of the tension forces when bracing the profiles have an elastic contact pressure that increases the resistance to sinking in the profile webs and an increase in the gap resistance of the profiles.

Fig. 4 shows two nested in the untensioned state Profiles whose profile shape is similar to that of FIGS. 1-3. However the hyperbolic boundary lines 4 and 5 of the webs 2 are designed in such a way that that the asymptote angle of the outer boundary lines 5 are greater than the asymptote angle the inner delimitation lines 4. This ensures that the profiles in the unstrained State only touch in the area of their upper flange ends. The contours the flange straps 3 are at the transition between the inner web boundary lines 4 and the flanges 3 and at the transition between the outer boundary lines 5 and the flanges 3, as can be seen at 3a and 3b, arcuate in the way, that when the profiles are pressed together, the surfaces 3a of the outer profile and the Areas 3b of the inner profile are wholly or partially on top of one another. With the profile According to FIG. 4, the pressure forces between the webs 2 are in the region of the upper web ends the biggest. Here, too, the special design of the flanges creates the gap resistance of the profile is increased and the web of the outer profile is elastic against the web of the inner profile pressed on.

Figs. 5-7 show the arrangement of a known pull strap to generate an increased sinking resistance of the loaded extension frame. Around the nested profiles are placed two brackets 13 and 14, which under the Grip the flange straps 3 of the outer profile. The brackets 13 and 14 are respectively arranged at the ends of the two overlapping segments 11 and 12. The recesses 15 of the brackets 14, in which the hook-shaped straps of the profiles enclose, are limited by surfaces or stops 16 (Fig. 7) against which the end faces of the segments.

The two brackets are therefore each at the ends of the one inside the other Segments 11 and 12 arranged in such a way that the brackets 13 from the segment 12 and the clamps 14 is taken along by the segment 11 when it is inserted. the the two clamps 13 and 14 are connected to one another by means of a tension band 17. The drawstring 17 has a loop-shaped end 17a through which a flat one Cross bolt 18 is pushed through. The cross bolt 18 is supported on the bracket 14 from. The tension band 17 located in the interior of the inner segment 11 is over a deformation bead or bolts 18 of the clamp 13 passed around 180 degrees. The bolt 18 is in a attached to the bracket 13 pocket 19 which engages in the inner segment.

The end 17b of the drawstring lies outside the overlap area of the two segments 11 and 12 in the outer segment 12.

It can be seen cbß when inserting the two segments 11 and 12 the brackets 13 and 14 are taken and pushed apart, at the same time the drawstring 17 is pulled over the bolt 18 with deformation. The deformation resistance of the drawstring determines the level of resistance to sinking.

The brackets 13 and 14 can be used to brace the two at the same time Segments 11 and 12 or to press the profiles together. To this end For example, wedges can be placed between the flange straps 3 of the outer segment 12 and the brackets 15 are struck. But it is also possible for bracing the segments special clamping means, for example brackets, brackets or the like. To be provided. The ones in the Fig. 5-7 shown device for increasing the sinking resistance is of course also suitable for other channel-like support profiles. Protection claims

Claims (6)

Protection claims: ------------------------------- 1. A channel-like expansion profile for mining operations, tunnel construction or the like, in particular for underground route expansion by means of a sliding arch expansion consisting of several segments in a ring or arch shape, in which the ends of the segments lie one inside the other in the same direction and can be braced together in the overlapping area, characterized in that, that the flange webs (2) of the profile inside and outside of the profile are limited by hyperbolic curves lying one above the other in the Y-direction, the asymptote angles () of the outer and inner hyperbolic boundary lines (4, 5) being either the same or different, but preferably the asymptote angle () of the outer boundary line (5) is smaller than that () of the inner boundary line (4). 2. Extension profile according to claim 1, characterized in that the flange straps of the profile are designed such that when bracing two in the overlap area nested segments (11, 12) by pressing the flange straps against one another (3) the flange webs (2) of the outer profile resiliently counter to the inside of the profile the flange webs (2) of the inner profile are pressed. 3. Extension profile according to claims 1 and 2, characterized in that that the flange straps (3) of the profile are pulled downwards in the shape of a hook, such that when the profiles lie one inside the other, the flange chords (3) of the inner profile partially encompass the flange straps of the outer profile. 4. Extension profile according to one of claims 1-3, characterized in that that the flange belts (3) are designed to taper towards the top. 5. expansion profile according to claim 4, characterized in that the contours the flange straps (3) at the transition between the inner web boundary lines (4) and the flanges (3) and at the transition between the outer ones. Web boundary lines (5) and the flanges (3) arcuate (3a or 3b) shaped to correspond to one another are. 6. Extension frame with a profile according to any one of claims 1-5, characterized by means of a tension band, known per se, arranged between the segments for generation a sinking resistance of the extension frame.