EP0954644A1

EP0954644A1 - Mobile anti-flood protection device

Info

Publication number: EP0954644A1
Application number: EP97945777A
Authority: EP
Inventors: Hans-Joachim Krill; Klaus Heringhaus
Original assignee: KRILL HANS JOACHIM
Current assignee: KRILL HANS JOACHIM
Priority date: 1996-11-20
Filing date: 1997-10-23
Publication date: 1999-11-10
Anticipated expiration: 2017-10-23
Also published as: DE59703628D1; WO1998022659A1; ATE201469T1; EP0954644B1; DE29620193U1; PL333372A1; US6450733B1; CZ174799A3; SK282505B6; CZ292814B6; PL184841B1; SK65099A3

Abstract

A mobile anti-flood protection device comprising flexible tubes (1) placed on top of each other with closed ends and at least one water connection. The ends of the tubes (1) are detachably fixed to holding devices (2). The holding devices are removably secured to a base plate (3a) which is fastened to a substructure (3) to be included in the ground.

Description

Mobile device for protection against flooding

Measures to protect against floods can be found in a large number of bodies of water. Usually these are permanently installed structural measures, such as those shown by dikes. In addition, mobile flood protection devices are known which are installed at the locations provided for the expected flood. These are usually steel plates, with the help of which passages in the dikes, for example, are "sealed off". These mobile flood protection devices have the disadvantage that they are difficult to transport and their area of use is limited to the passages in dykes.

In addition, the following problem arises: On the one hand, the risk of flooding increases due to the warming of the earth's atmosphere, the resulting intensification of precipitation water and the melting of snow. On the other hand, the ever-increasing land consumption of people also affects alluvial landscapes, which act as "catch basins" when floods occur and thus slow the rise in flood levels. As a result, the latter are often no longer sufficient, so that there is a risk of the flood level exceeding the dike height. The dyke systems therefore urgently need to be increased or renewed or extended in order to exceed the To prevent dikes from flooding. Such an increase in the dikes is associated with considerable costs. In addition, the available space is often not sufficient to allow the dyke systems to be enlarged.

The invention seeks to remedy this. The invention has for its object to provide a device for protection against flooding, which allows a simple way to reinforce the existing flood protection measures and is inexpensive. According to the invention, this object is achieved by hoses arranged one above the other, closed at their ends, which have at least one water connection and which are detachably fastened with the ends in holding devices, which in turn are releasably anchored to a base plate which is fastened to a substructure to be provided in the ground .

With the invention, a mobile device for protection against flooding is created, in which the effort in terms of working time and material during transport and during assembly and disassembly is significantly reduced. In addition, the simple assembly of the device according to the invention leads to a noticeable reduction in costs. In addition, flood protection in uneven terrain is possible due to the adaptation of the hoses to the terrain. Furthermore, there is the possibility of producing radii in almost any manner with the aid of the device without problems, so that the device can be carried out without problems along the course of the water.

In a development of the invention, the hoses are detachably connected to one another. The stability of the device is significantly increased by connecting the tubes to one another. The detachability of the connection of the hoses to one another also enables the device to be easily transported to the respective place of use.

The hoses advantageously have a substantially square cross section. Due to this cross-section, the contact surface of the hoses with one another is increased, as a result of which the hoses are sealed properly. This also creates a more even contact surface. In an embodiment of the invention, the water connections are designed in the form of plug connectors. With the help of the connectors, a simple and quick connection of water pipes to the hoses is possible.

A check valve is preferably arranged in each case in the water connections, as a result of which overfilling of the hoses with water and any resulting bursting of the hoses is prevented. In addition, the filling quantity can be limited to a predetermined level by selecting an adjustable check valve.

In a further embodiment of the invention, water pipes are connected to the water connections and are connected to a pump. A float regulator is preferably connected to the pump. This makes it possible to fill the hoses with water depending on the flood level, so that all hoses of the device according to the invention do not have to be filled with water from the beginning. The time required to set up the device is thus reduced. In addition, the floating regulator enables the hoses to be filled up with water independently, depending on the respective flood level, which means that personnel expenditure is kept to a minimum.

Finally, in an embodiment of the invention, supports are provided between the brackets and are releasably attached to foot plates provided in the floor. By providing supports along the device according to the invention, it is possible to protect very long sections against flooding with the aid of the hoses.

An embodiment of the invention is shown in the drawing and will be described in more detail below. Show it:

Figure 1 is a view of the device from the side facing away from the watercourse on a scale of 1: 250; Figure 2 is a top view of the device shown in Figure 1; 3 shows a vertical section through the device shown in Figure 1 along the line AA in Figure 1; 4 shows a vertical section through the device shown in FIG. 1 along the line BB in FIG. 1.

A mobile device for protection against flooding has hoses 1 arranged in layers one above the other. The height of the device and thus the number of hoses 1 arranged one above the other is variable and depends on the expected flood level at the respective place of use. The mobile device chosen as an exemplary embodiment has eight hoses 1 arranged one above the other. The ends of the hoses 1 are detachably fastened in holding devices 2. The holding devices 2 are also releasably attached to base plates 3a. The floor slabs 3a are concreted into a substructure 3 provided in the floor. In the longitudinal direction, the device has support devices 4 at a distance from one another, which are releasably attached to base plates 5. The base plates 5 are each concreted into a substructure 3.

The tubes 1 have an essentially square cross section. They are made of rubber, and one or more layers of fabrics that increase the stability of the tubes can be incorporated into the rubber. In the longitudinal direction, the tubes 1 have connectors at regular intervals, with the aid of which the tubes 1 are detachably connected to one another. The connectors can be, for example, coupling locks or simple plug connectors. The tubes 1 each have at least one - not shown - water connection, which is vulcanized into the tubes 1. The water connections are in the form of plug-in couplings and each contain a check valve. At its closed ends, the tubes 1 have eyelets 11 with which the tubes 1 are suspended in the holding devices 2. The length of the hoses 1 and the dimensions of the cross section of the hoses 1 are determined by the local conditions and the static conditions as a result of the height of the flooding that occurs. In addition, the transportability of the hoses must be taken into account when determining the dimensions. Each holding device 2 consists essentially of a U-shaped steel profile 21. There is a sealing profile 22 on the outside of the U-shaped steel profile 21. On its side facing away from the hoses 1, the U-steel profile 21 has bores through which screw bolts 23 can be inserted, followed by U profiles

Flood protection devices to be screwed together, so that the connection of the U-steel profiles to each other is watertight - Figures 1, 2 -. 1 steel holding T-profiles 26 are welded into the U-steel profiles 21 for hanging the hoses 1 by means of the eyelets. This makes it possible to ensure reliable flood protection even over long distances, for example along a river course. T-steel struts 24 are arranged on the U-steel profiles 21 at an angle - in the exemplary embodiment approximately 50 °. The T-steel struts 24 are screwed to the U-steel profiles 21. Flat struts 24a are arranged on the struts 24 at an angle - in the exemplary embodiment approximately 80 ° - which are also screwed to the U-steel profiles 21. All steel profiles are galvanized and therefore not rusting. The screws, nuts, bolts are made of rust-free precious metal. At their ends facing away from the U-steel profiles 21, the struts 24 are provided with base plates 25. The base plates 25 are screwed to the base plates 3a.

The substructure 3 is made, for example, of reinforced concrete. On the base plates 3a. steel anchors 31 a are welded on the underside and are embedded in concrete in the substructure 3. The foot plates 25 of the holding device 2 are fastened on the base plates 3 a by means of screws 31. In the non-assembled state of the device, steel plates are screwed onto the base plates 3a as covers with the screws 31, which have the same dimensions as the foot plates 25.

The support device 4 has double T-steel supports 41 on its side facing away from the water course. On the side of the hoses opposite the steel supports 41 - the side of the hoses facing the water course - the

Support device 4 T-steel supports 42 on. The hoses 1 are thus held between the supports 41 and 42. The distance between the supports 41 and 42 is aligned according to the dimensions of the hoses 1 in a state filled with water. On the supports 41 are T-steel struts 43 in to the steel struts 24 of the holding device

2 arranged in a comparable manner at an angle of approximately 50 °. The steel struts 43 also have flat steel struts 44 which are fastened to the steel supports 41 at an angle of approximately 80 ° to them. The steel supports 41, 42 and the steel struts 43 are provided with base plates 45.

The support devices 4 are mounted on the base plates 5 concreted in the substructure 3 in a manner comparable to the holding devices 2. The base plates 45 are fastened to the base plates 5 by means of screws 51.

A pump 6 is arranged on the side facing the water course. In the exemplary embodiment, it is an electric water suction and pressure pump which is connected to the water connections of the hoses 1 via inlet hoses 62. In the drawing, only one inlet hose 62 to a hose 1 is shown as an example; in practice, each hose 1 is connected to the pump 6 by means of an inlet hose 62. In addition, when several water connections are made to one hose 1 each, it is possible to connect to several pumps 6 via inlet hoses 62. The pump 6 has a float controller 61 - Figure 4 -. With the help of the float regulator 61, the pump 6 in works

Dependence on the flood level. In the case of the use in the flood area shown in the exemplary embodiment, the pump 6 is to be equipped with a dirty water filter in order to prevent it from becoming blocked by sediments carried in the flood. It is also possible not to use the pump 6 in the area of the flood, but to take water from public drainage systems.

When assembling the device according to the invention, the holding devices 2 on the base plate 3 and the support devices 4 on the substructure are first

3 erected. Subsequently, the hoses 1 are arranged in layers between the devices 2 and 4 in the unfilled state. This can be done, for example, using hose reels and unrollers specially used for this purpose. The hoses 1 are then connected to one another in the longitudinal direction and to those at their ends Arranged eyelets 1 1 hooked into the holding devices 2. When the flood occurs, the hoses 1 are filled with water by the pump 6, starting from the side facing the ground (lowest position). When the controller 61 is used, this filling takes place automatically. The regulation is to be carried out in such a way that at least 1.5 tube layers above the respective flood level are always filled with water in order to counteract the buoyancy of the tubes 1 which are already in contact with the flood. The hoses 1 are filled by the pump 6 via the inlet hoses 62 through the water connections to the hoses 1. The degree of filling of the hoses 1 is approximately 90% of their volume, in order to bring about a widening of the support and additionally to make the hoses 1 lay more smoothly against one another, which leads to a perfect seal against the flood. The degree of filling is regulated by means of the check valve integrated in the water connections. The sealing in the holding devices 2 takes place during the filling of the hoses 1 with water, in which the ends of the hoses 1 press against the U-steel profiles 21.

When the flood level drops, the filling water of the hoses 1 is pumped out in the same rhythm starting from the top hose position. Here too, at least 1.5 hose layers always remain filled with water above the respective flood level. The hoses 1 are always filled and emptied depending on the respective flood level. If the water is pumped out of the hoses 1, the hoses lie flat on top of each other, so that they assume the same position as after rolling out when assembling the device. After loosening the hoses 1 from the holding devices 2 and the connections to one another, the hoses can be rolled up and removed in a simple manner. The holding device 2 and the supporting device 4 are dismantled in the reverse order to the construction of the device.

The device according to the invention can also be used for flood protection. For this purpose, it is necessary to have non-positive connections in the building exterior wall surfaces to be enclosed at a predetermined distance, one below the other and next to each other Drill in dowels as screw-on anchors with cover caps. If there is a risk of flooding, steel retaining structures in the form of double-T steel profiles are screwed onto the wall screw anchors and then custom-made hoses 1 are hung into the profiles with the eyelets 1 1 depending on the expected static stress due to the flooding. The hoses 1 are filled and emptied in the manner described above. The dismantling takes place in the reverse order to the assembly. For flood protection, the device is advantageously stored in the object to be protected.

In addition, it is possible to use the device according to the invention for securing stressed dike areas and for increasing them. On a prepared substructure, assembly and disassembly as well as filling and emptying of the device is carried out in the manner described above.

There is also the possibility of isolating existing dyke systems from the water by installing upstream mobile water protection wall elements in order to repair the existing dyke systems. On steel structures that are anchored and supported in the bottom of the water, water-filled hose elements are sunk in layers, taking into account the water buoyancy, using guide rails on guide rails to the bottom. Afterwards the enclosed water can be pumped out. The hose layers are disassembled by pumping out the respective upper layer and pushing it up to the water surface through the water buoyancy. The steel holding structure is then dismantled.

Furthermore, the device according to the invention can be used in caisson construction. For this purpose, the device is constructed, for example, round, square or oval. After inserting the steel support structure with anchoring into the water, closed and water-filled hose rings are sunk in layers down to the bottom of the water. After sealing, the inside of the

Caisson's water is pumped out so that a wide variety of activities can be carried out in the dry area. The caisson is dismantled by continuously pumping the water out of the upper hose layers, which pushes the hoses up due to the water buoyancy. The holding and supporting device is then dismantled in the reverse order to the assembly.

Claims

Protection claims

1 . Mobile device for protection against flooding, characterized by hoses (1) arranged one above the other and closed at their ends, which have at least one water connection and are detachably fastened with the ends in holding devices (2), which in turn are releasably anchored on a base plate (3a) , which is attached to a base (3) to be provided in the floor.

2. Device according to claim 1, characterized in that the hoses (1) are detachably interconnected.

3. Apparatus according to claim 1 or 2, characterized in that the hoses (1) have a substantially square cross section.

4. Device according to one of claims 1 to 3, characterized in that the water connections are designed in the form of plug connections.

5. Device according to one of claims 1 to 4, characterized in that in each case a check valve is arranged in the water connections.

6. Device according to one of claims 1 to 5, characterized in that a pump (6) via inlet hoses (62) is connected to the water connections of the hoses (1).

7. The device according to claim 6, characterized in that the pump (6) has a float controller (61).

8. Device according to one of claims 1 to 7, characterized in that between the holding devices (2) support devices (4) are provided which are releasably attached to base plates (5) which are arranged on the base (3).

9. Device according to one of claims 1 to 8, characterized in that the holding devices (2) at their ends facing the base plates (3a) have base plates (25) which are screwed onto the base plates (3a) with screws (31).

10. The device according to claim 8 or 9, characterized in that the support devices (4) at their bottom plates (5) facing ends have foot plates (45) which are screwed onto the bottom plates (5) with screws (51).