DE8906507U1 - Doks building material support - Google Patents

Description

Description

The invention relates to a device for securing rooms by bracing a support between ceiling and floor, in particular mined cavities in underground mining and tunnel construction, consisting of a fabric container made of water-permeable, high-strength thread with a filling opening for the pumpable and hardening building material or a similar support material and with a support frame adapted or adaptable to the shape of the fabric container.

It is known to produce building material supports, i.e. a type of pillar, in a square, round or polygonal shape from concrete, whereby the pillar or the support is first covered with formwork in order to bring the concrete or other building material into the appropriate shape. In the above-ground area, the formwork is made from wood or other material, whereby it must be adapted to the respective application. The concrete or building material is then poured in from above until the corresponding support has reached its intended height. The material then hardens in order to then be used to support corresponding ceiling structures or the like.

In underground mining it is known (DBP 2o 12 269) to create a container from foldable material, i.e. mainly jute fabric and plastic thread fabric, into which the building material is filled. This container, which is also known in principle from DE-GM 75 31 698, is equipped with a filling valve and, if necessary, with ventilation openings in order to allow the air displaced when the building material is filled in to escape as quickly as possible. The containers are adapted to the cavity to be filled or secured and are usually rectangular in shape, with the height of the rectangle depending on the distance between the hanging and lying parts. Side formwork has also been used here to ensure compliance with the specified

shape of the container. In particular, this ensures that the container, which is subsequently filled with concrete or building material, does not bulge, but rather has walls that are as vertical as possible.

Finally, from DE-OS 37 32 894.8, slim-bearing structural members are known in which a tube-shaped fabric container is suspended in a formwork tube and then filled with building material so that the excess water can escape through the fabric and then the pipe formwork provided with holes.

A disadvantage of these known devices and especially the method known from DE-OS 37 32 894 is that a separate formwork is required, which must therefore remain on the pillar or column until the building material has hardened accordingly. Another disadvantage is that the shape of the fabric container must at least approximately correspond to that of the cavity to be filled, otherwise correct and sufficient bracing between the hanging and the lying parts cannot be achieved. Another particularly disadvantage is that the support forces that can be absorbed by the building material support are relatively limited, because only reinforcement forces are applied by the fabric container, whereas otherwise only the building material is able to absorb forces.

The invention is therefore based on the object of creating a Gev'-ebe container that can absorb high supporting forces without chipping off the building material and is completed when the building material is filled in, i.e. can be erected easily and quickly.

The object is achieved according to the invention in that the support structure is arranged within the tissue container completely surrounded by the tissue and the height or length of the

Building material support is designed accordingly.

This makes it possible to transport the support frame or the entire building material support without building material cheaply and without great effort, whereby both the support frame and the fabric container can be transported alone or in combination. The support frame can be roughly adjusted to the respective height of the cavity to be secured, but can also be adjusted underground or at the site without great effort by simply shortening the longitudinal elements of the support frame accordingly or extending them by attaching a shorter support frame. The fabric container, which consists of water-permeable, high-strength threads, is easily able to absorb the forces exerted by the flowable building material, whereby the support frame, which is preferably made of iron, is so completely covered that subsequent flaking due to rust or influences from rust cannot occur. What is particularly advantageous, however, is that this support structure, which is systematically wrapped in the building material, can take on very high supporting forces, even without the need for additional measures and while maintaining the appropriate security provided by the fabric container itself. What is particularly advantageous, however, is that a separate formwork is not required when upgrading the building material support, so that the production process is completed immediately when the building material is filled in. This means that you no longer need to wait until the building material has hardened in order to then remove the formwork that was previously used and use it for another building material support. Advantageously, one building material support can be filled after the other in order to complete the entire work. This is particularly advantageous because a large number of such building material supports can be prepared with support structures and fabric containers, so that a whole series of these building material supports can then be filled in practically in one operation by filling

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of the building material.

According to an expedient embodiment of the invention, the support frame is loosely covered by the fabric of the fabric container. This ensures that the building material shell around the support frame is of uniform thickness, so that the building material support or the inner frame is not endangered by moisture, etc. In this case, further securing of the support frame can be achieved by the longitudinal wires and the ring elements of the support frame having a plastic coating.

The filling process is made easier by the fact that the fabric container has an integrated filling valve, is tubular and is closed at both ends. By pumping in the building material via the filling valve, a tension can be achieved at the same time between the ceiling and the floor or between the hanging and the lying, so that the early bearing effect of a ram is achieved, which brings with it considerable advantages, especially in underground mining.

The forces to be absorbed by the fabric container can be increased in a targeted manner by making the fabric container out of round-woven fabric and by designing the support frame as a reinforcement cage that is open at the top and bottom. This means that reinforced components in the form of the reinforcement cage are used, which is inserted into the fabric container, whereby the forces are absorbed effectively by eliminating seams. The support frame or reinforcement cage is open at the top and bottom so that the material or building material can penetrate into the interior of the building material support without obstruction.

Where closed baskets are desired, this can be

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can be achieved without any problems, since the reinforcement cage or its ends are assigned to 1 flat grids, the diameter of which is chosen to be slightly larger than that of the reinforcement cage. The flat grids are placed on the reinforcement cage or the reinforcement cage is placed on the lower flat grid, so that reinforcement is also provided to stabilize the reinforcement cage. It is also conceivable to use flat grids that are smaller in diameter than the reinforcement cage, but have extended rods so that they can also be inserted in the middle of the reinforcement cages.

The support scaffold according to the invention is particularly simple to construct and inexpensive if the reinforcement cage used as the support scaffold consists of a welded mesh with circular ring elements. Such reinforcement cages are also used above ground for other purposes.

In order to ensure good stability for the support frame or the support frame and the fabric container pulled over it, the invention provides that the reinforcement cage serving as the support frame has longitudinal wires, the ends of which are equipped with support feet. The support feet are either pushed onto the ends of the longitudinal rods and then stand on the fabric container base, or they are pushed through the fabric container base so that the fabric container is also fixed to the support frame at the same time.

Depending on the application, it may be appropriate to produce building material supports with a cross-section that differs from the round one, which can be achieved by designing the horizontal ring elements of the reinforcement cage as a polygon, preferably an octagon. The longitudinal bars can be arranged at the corner points and connected to the correspondingly short ring elements or rather the segments of the ring elements.

It is also possible to bend the ring elements and then connect them to the longitudinal wires.

Depending on the diameter of such a building material support
can be provided to improve the reinforcement, the
Supporting framework of several nested, preferably
of two reinforcement cages. This results in

3 ILIl CIII IIUIIC J^UM &agr;&idigr;&iacgr;&idiagr;: OUIIICIIIIICIIUCI nCI II) »&Idigr; I/ U C 1 UC" OUUCII The fabric container that sits on the wall only has to absorb the transverse forces emanating from the building material and is therefore practically not loaded. Nevertheless, such a building material support has extremely favorable support properties.

Another possibility to support the entire building material
to be provided with reinforcement is the one in which a reinforcement part similar to a chimney sweep's broom is arranged in the support frame, the protruding wires of which extend into the reinforcement cage. The upgrade
of such a building material support is extremely simple, because the already prepared reinforcement part is simply inserted into the reinforcement

wires are positioned simultaneously. The building material can
flow through the reinforcement part or its wires and envelop them and the reinforcement cage, so that an optimally reinforced building material body is created.

The reinforcement part serves according to a further development
at the same time as a fixing aid for the fabric container, in which the wires of the reinforcement part act as spacers for the
Fabric containers are dimensioned to be effective, ie they penetrate the reinforcement cage and protrude beyond its rods or wires, so that the fabric container is kept at the same distance from the reinforcement cage from the outset, whereby ^{this is} optimally enclosed by the building material.
becomes.

Due to variations in the thickness of the seams in underground mining, it is unavoidable that the support structure used has to be adjusted underground. This can be done simply by shortening the longitudinal wires accordingly, which is made easier by the fact that the longitudinal wires of the support structure are provided with weak points at a distance that also allow the longitudinal wires to be bent or twisted. These weak points can also be used to bend the longitudinal wires accordingly, so that an arched structure or the like is created, which also allows for favorable adjustment to the changing conditions in this respect. At the same time, these weak points can be used to shorten the support structure accordingly, which also makes it possible to put the shortened section of the support structure back on top, whereby the parts of the support structure then slide into each other, resulting in an overall shortening.

Where the supplied building material support is too short due to local conditions, it can still be used perfectly, since according to a further development of the invention, the upper and/or lower end of the fabric container is connected to a cushion or fabric sack with its own filling valve. This fabric sack will only need to be used if the building material support cannot otherwise be braced between the hanging and lying parts or the floor and ceiling. The fabric sack is then simply placed on top of the already completed support and filled with building material, automatically creating a system that ensures the effectiveness of the building material support. Where an additional difference needs to be compensated, a corresponding fabric sack is simply placed on the lying part and the building material support is placed on top of it, so that an appropriate addition is also possible without any problems.

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The invention is particularly characterized by the fact that a building material support is created which can be easily transported even in confined underground conditions and, above all, can be set up and erected in a very short time. The support frame and the fabric container can be transported separately or together, and after the support frame has been pushed into the fabric container, the latter can simply be connected _to the building material supply in order to fill the building material up to the top. The building material itself is prevented from leaking out by the fabric container, whereby the excess water can escape so that the building material hardens quickly, and additional formwork can be completely dispensed with. The support frame then provides advantageous reinforcement so that such a building material support can absorb high forces. Another advantage is that by adding to or modifying the support frame, but above all by using reinforcement cages, reinforcement for such building material supports can be created which can be adapted to the respective application conditions.

Further details and advantages of the subject matter of the invention are apparent from the following description of the accompanying drawing, in which preferred embodiments are shown with the necessary details and individual parts. They show:

a building material support in section, in which

the building material has not yet been filled,

a building material column filled with building material

with fabric bag on top,

the lower part of a building material support in

Cut,

a scaffold in side view,

the support frame or a grid for laying

of the scaffolding in plan view,

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Fig. 6 a circular support frame, Fig. 7 two support frames placed inside each other, Fig. 8 a polygonal support frame, Fig. 9 a support frame made up of triangles in plan view, Fig. 10 a support frame with additional reinforcement

part,
Fig. 11 a device equipped only with ring elements!

building material support,

Fig. 12 a single support element in plan view* Fig. 13 several building material supports in use and
Fig. 14 an angled building material support.

Fig. 1 shows a cross-section of a building material support (1) which is to be installed in a cavity (2), here a longwall, in order to secure the cavity (2) and to be braced between the overhead structure (13) and the underlying structure (4). A building material support (1) is shown before the building material is filled in. This building material can be filled into the fabric container (6) via the individual opening (5) in order to then surround the support structure (7) or through the filling valve (8) at a height of around 1 1/2 to 2 m. This filling valve (8) is integrated into the fabric (9) of the fabric container (6) in such a way that it can then remain on or in the building material support without any problems.

The upper end (lo) of the building material support (1) is formed by the filling opening marked (5), whereby the interior of the fabric container (6) can be closed via a locking ring (11) when sufficient building material has been filled in. As a rule, the filling valve (8) is used because this makes it possible to effectively seal a fabric container (6) that is sealed at the upper end (lo) and the lower end (12) between the overhead and the underlying surface, supported by the support structure (7).

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tighten.

The support structure consists of longitudinal wires (13, 14) and ring elements (15, 16) connected to them, mainly welded. This creates a reinforcement cage (17) which can be inserted into the mesh container (6) as a stable system.

If the length of the reinforcement cage (17) or the support frame (7) is too short, the building material support (1) can still be used effectively by assigning it a fabric bag (18) with a filling valve (19). This fabric bag (18) is sewn onto the side of the fabric container (6), for example, and can therefore be removed and placed on top if necessary, whereby effective bracing between the hanging structure (3) and the building material support (1) itself is achieved by filling the building material through the filling valve (19). Fig. 2 shows such a situation very clearly.

Fig. 3 shows the lower area of a building material support (1) with an integrated support frame (7) and the fabric container (6) surrounding it. The support frame (7) has support feet (2o) at the lower end of the longitudinal wires (13, 14), which in the design shown in Fig. 3 have sleeves that are pushed through the bottom of the fabric container (6) onto the ends of the longitudinal wires (13, 14). These support feet (2o, 2o') initially connect the fabric container (6) in the lower area to the support frame (7), which can have advantages especially for transport. In addition, the building material support is also in a favorable position before the building material is filled in. The better stability of the unfilled building material support has advantages because a large number of such building material supports can now be set up and then continuously filled one after the other with building material. But even without

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these support feet (2o, 2o ¹ ) the reinforcement cage (17) as such already has favorable standing properties.

A reinforcement cage (17) or a support frame (7) made up of longitudinal wires (13, 14) and ring elements (15, IG). Here, the ring elements are shown as circular and are equipped with a few weak points (21, 22) in the upper area, which allow the reinforcement cage (17) to be shortened without any problems if necessary. Weak points (21, 22) provided at a distance are indicated to illustrate that it is also possible to angle the longitudinal wires (13, 14) in order to achieve a construction similar to that shown in Fig. 14. The grid (23) shown in Fig. 5 can be placed on top of the upper end (lo) of the reinforcement cage (17) in order to close off such a reinforcement cage (17). It is also conceivable to install surface-shaped grids (23) distributed over the height in order to provide additional reinforcement.

The reinforcement cage (17) shown in Fig. 4 is shown in a top view in Fig. 6, whereby the longitudinal wires (13, 14) can be arranged on the inside or on the outside of the ring elements (15) as shown. According to Fig. 7, the longitudinal wires (13, 14) are provided on alternate sides of the ring element (15) and a second reinforcement cage (26) is additionally inserted inside, which has a correspondingly reduced diameter compared to the reinforcement cage (17). It is clear that this results in very favorable core reinforcement.

Fig. 8 and 9 show polygons (24, 25) for the ring elements (15, 16), so that there is a very good possibility of changing the exterior of the building material support (1) in each case. The design according to Fig. 9 also has the advantage that the nested polygons (25, 25') provide additional stabilization.

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Fig. 10 shows a reinforcement cage (17) which is completed by an inserted reinforcement part (27). This also results in improved core reinforcement, with the reinforcement part (27) being designed like a chimney sweep's broom. The middle wire is surrounded by a large number of outwardly projecting wires (28, 29), with these wires (28, 29) reaching up to the reinforcement cage (17) or even penetrating it.

The embodiment according to Fig. 11 differs from those previously explained in that no reinforcement cage is used, but rather a large number of reinforcement rings, which are connected to the fabric container (6) by fastening, for example. They lie on the inside of the fabric container and provide reinforcement, albeit not as advantageous as that shown and described in the previous figures. Such a fabric container (6) is filled with building material (30), which is mainly pumped in, whereby the right half of Fig. 11 shows a folded fabric container (6) with ring elements (15, 16), which also has a filling valve (8). The individual rings (15, 15) can then be provided with support rods (31, 32) and reinforced according to Fig. 12 if corresponding problems arise with the embodiment shown in Fig. 11.

Fig. 13 shows a cavity, for example a strut seam, which is secured by several of the building material supports (1, 1') according to the invention. Inside the building material supports already filled with building material (3o), the support frame (7) which is surrounded by the fabric container (6) is indicated.

According to Fig. 14, supporting structures (7) of appropriate length can also be bent and angled once or several times to form a kind of arch, as shown in Fig. 14. Such structures can be filled with building material (3o) without any problems.

Claims (1)

II*· · ff Ii &Aacgr; &eegr; s &rgr; r ü che 1. Device for securing rooms by bracing a support between ceiling and floor, in particular mined cavities in underground mining and tunnel construction, consisting of a fabric container made of water-permeable, high-strength threads with a filling opening for the pumpable and hardening building material or a similar supporting material and with a support frame adapted to the shape of the fabric container and adaptable, characterized in that the support frame (7) is arranged within the fabric container (6) completely covered by the fabric (9) and the height or length of the building material support (1) is designed to predetermine it. 2. Device according to claim 1, characterized in that the support frame (7) is loosely wrapped by the fabric (9) of the fabric container (6). 3. Device according to claim 1, characterized in that the fabric container (6) has an integrated filling valve, is tubular and is closed at both ends (lo, 12). 4. Device according to claim 1 and claim 3, characterized in that the fabric container (6) consists of round-woven fabric (9) and the support frame (7) is designed as a reinforcement cage (17) that is open at the top and bottom. 5. Device according to claim 4, characterized in that the reinforcement cage (17) or its ends (10, 12) are assigned flat grids (23) whose diameter is selected to be slightly larger than that of the reinforcement cage. I lit · ·««· **ff « 6. Device according to claim 1 and claim 4, characterized in that the reinforcement cage (17) serving as a supporting framework (7) consists of a welded mesh with circular ring elements (15, 16). 7. Device according to claim 1 and claim 4, characterized in that the reinforcement cage (17) serving as a supporting framework (7) has longitudinal wires (13, 14) whose ends are equipped with support feet (2o). 8. Device according to claim 1 and claim 4, characterized in that the horizontal ring elements (15, 16) of the reinforcement cage (17) are designed as a polygon, preferably as an octagon. 9. Device according to claim 1 and claim 4, characterized in that the support structure (7) is formed by several, preferably two, reinforcing bars (17, 26) placed one inside the other. Device according to claim 1 and claim 4, characterized in that a reinforcing part (27) similar to a chimney sweep's broom is arranged in the support frame (7) , the projecting wires (28, 29) of which are designed to extend into the reinforcing cage (17). ti. Device according to claim lo, characterized in that the wires (28, 29) of the reinforcement part (27) are dimensioned to act as spacers for the fabric container (6). 12. Device according to claim 1, characterized in that the longitudinal wires (13, 14) and ring elements (15, 16) of the supporting frame (7) have a plastic coating. 13. Device according to claim 1, characterized in that the upper and/or lower end (lo, 12) of the fabric container (6) is connected to a cushion or fabric bag (18) having its own filling valve (19). 14. Device according to claim 1, characterized in that the longitudinal wires (13, 14) of the support frame (7) are provided with weak points (21, 22) at a distance from one another, which also enable the longitudinal wires to be kinked or bent.