阅读说明：本技术 用于排出液体的装置以及具有这种装置的建筑物围护构件 (Device for discharging liquid and building envelope with such a device ) 是由 F·沙伊迪 卡尔·迈瓦尔德 于 2018-11-30 设计创作，主要内容包括：一种用于从构成建筑物围护构件的至少一部分的第一薄膜层(4)中排出液体、特别是雨水的装置。第一阀元件(26)可以布置在设置在第一薄膜层(4)中的第一开口(22)的区域中,使得第一阀元件可以在封闭第一开口(22)的第一位置与至少部分地释放第一开口(22)的第二位置之间枢转。还设置有可安装在第一薄膜层(4)上的第一打开和闭合件(30,32,34),其被构造为,只要到达第一薄膜层(4)的上侧上的液体(40)的加载于第一阀元件(26)的压力(40a)小于预定的第一阈值或最高等于该阈值,就将第一阀元件(26)保持在第一位置,如果液体(40)的加载于第一阀元件(26)的压力(40a)超过第一阈值,则允许第一阀元件(26)从第一位置枢转到第二位置,在液体(40)的加载于第一阀元件(26)的压力(40a)基本上不再存在之后,第一阀元件(26)从第二位置枢转到第一位置。(A device for draining liquid, in particular rain water, from a first film layer (4) forming at least part of a building envelope. The first valve element (26) can be arranged in the region of a first opening (22) provided in the first film layer (4) such that it can be pivoted between a first position closing the first opening (22) and a second position at least partially releasing the first opening (22). Also provided is a first opening and closing element (30, 32, 34) which can be mounted on the first film layer (4) and is designed to hold the first valve element (26) in the first position as long as the pressure (40a) of the liquid (40) on the upper side of the first film layer (4) which acts on the first valve element (26) is less than a predetermined first threshold value or at most equal to the threshold value, to allow the first valve element (26) to pivot from the first position into the second position if the pressure (40a) of the liquid (40) which acts on the first valve element (26) exceeds the first threshold value, and to pivot the first valve element (26) from the second position into the first position after the pressure (40a) of the liquid (40) which acts on the first valve element (26) is substantially no longer present.)

1. A device for draining liquid, in particular rain water, from a first film layer (4) forming at least part of a building envelope, characterised in that it is provided with

A first valve element (26) which can be arranged in the region of a first opening (22) provided in the first film layer (4) such that it can be pivoted between a first position closing the first opening (22) and a second position at least partially opening the first opening (22); and

a first opening and closing member (30, 32, 34) capable of being mounted on the first film layer (4), the first opening and closing element being designed to hold the first valve element (26) in the first position as long as a pressure (40a) of the liquid (40) on the upper side of the first film layer (4) which is applied to the first valve element (26) is less than a predetermined first threshold value or at most equal to the threshold value, if the pressure (40a) of the liquid (40) loading the first valve element (26) exceeds the first threshold value, allowing the first valve element (26) to pivot from the first position to the second position, and after the pressure (40a) of the liquid (40) loaded on the first valve element (26) is substantially no longer present, the first valve element (26) pivots from the second position to the first position.

2. Device according to claim 1, for draining liquid from a second film layer (6) forming at least another part of the building envelope and limiting the cavity (12) of the film mat (2) together with the first film layer (4), characterised in that it is provided with

A second valve element (26) which can be arranged in the region of a second opening (22) provided in the second film layer (6) such that it can be pivoted between a first position closing the second opening (22) and a second position at least partially opening the second opening (22); and

a second opening and closing member (30, 32, 34) which can be mounted on the second film layer (6), the second opening and closing member being designed to keep the second valve element (26) in the first position as long as a pressure (40a) of the liquid (40) reaching the upper side of the second film layer (6) loaded on the second valve element (26) is less than a predetermined second threshold value or at most equal to this threshold value, if the pressure (40a) of the liquid (40) loaded on the second valve element (26) exceeds the second threshold value, allowing the second valve element (26) to pivot from the first position to the second position, and after the pressure (40a) of the liquid (40) loaded on the second valve element (26) is substantially no longer present, the second valve element (26) pivots from the second position to the first position.

3. A device according to claim 1 or 2, characterised in that the valve element is designed as a flexible or elastic pressure plate which can be fixed at one end to the film layer and at the other end can be moved relative to the opening.

4. A device according to claim 3, wherein the valve element is at least partially made of a thin film material.

5. Device according to claim 1 or 2, characterized in that the valve element (26) is designed as a flap which can be pivoted with its one end (26a) about a hinge (28) which is mounted substantially fixedly with respect to the film layer (4; 6) and with its other end (26b) with respect to the opening (22).

6. A device according to claim 5, characterised in that the shutter constitutes a substantially rigid element.

7. Device according to at least one of the preceding claims, characterized in that the opening and closing member has a resetting member (30) which generates a resetting force for pivoting the valve element (26) from the second position in the direction towards the first position.

8. Device according to claim 7, characterized in that the return element has a spring mechanism (30) which generates a spring force as a return force.

9. Device according to claim 5 and claim 7 or 8, characterized in that the spring mechanism (30) has at least one helical spring which is arranged in the region of the hinge (28) or on the hinge (28).

10. Device according to at least one of claims 7 to 9, characterized in that the resetting force is determined such that the valve element remains in the first position as long as the pressure of the liquid loading the valve element is less than a threshold value or at most equal to a threshold value.

11. Device according to at least one of claims 1 to 9, characterized in that the opening and closing member has a first magnet element (32) which can be mounted on and/or in the film layer (4; 6) and a second magnet element (34) which is arranged on and/or in the valve element (26), wherein the two magnet elements (32; 34) are aligned with one another and are designed to generate an attractive force which acts on the two magnet elements (32; 34).

12. A device according to claim 11, characterized in that the suction force is determined to bring the valve element (26) into the first position and to remain in the first position if and as long as the pressure (40a) of the liquid (40) loading the valve element (26) is less than a threshold value or at most equal to a threshold value.

13. A device according to claim 11 or 12, characterized in that the attraction force is determined to bring the valve element (26) to the first position if the distance between two magnet elements (32; 34) is below a predetermined maximum value.

14. A device according to claim 8 or 9 and claim 13, characterised in that the resetting force is determined such that substantially only the weight of the valve element (26) is counteracted in order to pivot the valve element from the second position in the direction of the first position.

15. Device according to at least one of claims 11 to 14, characterized in that either (1.) the first magnet element (32) has a magnetic material and the second magnet element (34) has a magnetizable material, or (2.) the first magnet element (32) has a magnetizable material and the second magnet element (34) has a magnetic material, or (3.) both magnet elements (32; 34) have a magnetic material.

16. The device according to at least one of claims 11 to 15 and claim 3 or 5, characterized in that the second magnet element (34) is arranged on the valve element (26), in the region of the other end (26b) or adjacent to the other end (26b) thereof.

17. A building envelope having a first film layer as the only film layer and at least one apparatus according to at least one of the preceding claims except claim 2.

18. Building envelope with a film mat (2) having at least one first film layer (4) and a second film layer (6), wherein at least one substantially fluid-tight closed cavity (12) is formed between the first film layer (4) and the second film layer (6), in which cavity a fluid medium, in particular air, is contained and can be pressurized in the cavity (12), having at least one device (20a, 20b) according to at least one of the preceding claims.

Technical Field

The present invention relates to a device for draining liquid, in particular rain water, from a first film layer constituting at least a part of a building envelope. The invention also relates to a building envelope having a first film layer as the sole film layer. Finally, the invention relates to a building envelope with a film mat having at least one first film layer and a second film layer, wherein at least one substantially fluid-tight cavity is formed between the first film layer and the second film layer, in which cavity a fluid medium, in particular air, is contained and can be pressurized.

Background

Building envelope members of the aforementioned type are used in membrane roofing systems and membrane roofing systems. The field of application is in particular large commercial buildings, such as stadiums, activity centers or shopping centers. The advantages offered by membrane roofing systems, such as, inter alia, brightness, light transmission, adjustability of heat conduction, and/or designability of color schemes, are particularly useful for such large roof areas.

The applicant has developed, manufactured and marketed building envelope members of the aforementioned type. The building envelope is usually made of or consists of a film mat, wherein the film mat is formed by arranging at least two film layers which are locally spaced apart from one another. The two film layers of the film mat are welded to one another along their edges or joined to one another in a fluid-tight manner and form at least one substantially fluid-tightly closed cavity between them. The membrane mat is secured to a structure along the edges of the two membrane layers. Furthermore, a compressed air supply device is provided, which has, for example, a pipe, a channel and/or a hose and an external compressed air source connected thereto, in order to introduce air under pressure into the hollow space of the membrane mat. The pressure prevailing in the membrane mat is of great importance for its function, in particular its stability, insulating effect and resistance. In principle, it is also conceivable to use, instead of the membrane mats, single-layer membrane roofing systems or membrane roofing systems with only a single membrane layer, which are fastened to a structure with their edges in a tensioned state.

In the event of an unexpected loss of pressure in the membrane mat, the upper or outer membrane layer will lose its outwardly and upwardly curved shape and possibly collapse, i.e. collapse or be flaccid, so that it will first go into a horizontal orientation and then take on a downwardly curved "sagged" shape, whereby it then forms an upwardly or outwardly open depression. The same problem occurs in single-layer membrane roofing systems or membrane roofing systems when the stresses in the single membrane layer used are significantly reduced or even completely eliminated. In both cases, the collapsed film layer discussed herein forms a trough-like depression in which rain can now accumulate. As the inflow of rain water increases, the weight of the water accumulated on the upper side of the film layer increases, which then, due to the stretchability of the film layer, leads to an increase in the groove-like depression in the collapsed film layer and further subsidence, until the film layer is torn off or the retaining structure holding the film layer is damaged due to an overload caused by the increase in liquid.

To avoid the above, various methods have been proposed.

One approach is to arrange the film layers obliquely so that water can flow out accordingly. However, such an oblique arrangement is not reasonable for every application and every construction condition, and therefore leads to unnecessary limitations.

Another approach is to have the film layer be laid under significantly greater tension than before, or to use a film that is significantly less stretchable. However, it has been confirmed that: this measure is also very narrowly limited, so that a reliable drainage of rainwater cannot always be ensured even in the above-mentioned cases.

A further method is to use special monitoring systems with which the state of the film layer and/or, in the case of a film mat, the pressure build-up or pressure drop is monitored and, in the event of an error, a corresponding warning signal is generated. Apart from the fact that this is an indirect measure, i.e. that in the event of a fault other direct measures need to be taken to actually remove the rain, the following risks cannot be substantially completely ruled out: that is, faults or even complete failures may occur in such monitoring systems, so that errors cannot be identified.

Finally, another approach is to provide one or more drain hoses. In addition to the complexity of assembly and introduction of such hoses, particularly in the case of membrane mats, there is also the risk of kinking the hose as a result of the falling-down of the collapsed membrane layer and thus hindering further drainage of rainwater.

Disclosure of Invention

The object of the invention is therefore to provide a structural measure which ensures safe drainage of liquids, in particular rain water.

The object of the invention is achieved by a device for draining a liquid, in particular rain water, from a first film layer constituting at least a part of a building envelope, characterized in that: a first valve element which can be arranged in the region of a first opening provided in the first film layer, such that the first valve element can be pivoted between a first position closing the first opening and a second position at least partially opening the first opening; and a first opening and closing member mountable on the first film layer and designed to hold the first valve element in the first position as long as a pressure of the liquid on the upper side of the first film layer loaded on the first valve element is less than a predetermined first threshold value or is at most equal to the threshold value, to allow the first valve element to pivot from the first position to the second position if the pressure of the liquid on the first valve element exceeds the first threshold value, and to pivot from the second position to the first position after the pressure of the liquid on the first valve element is substantially no longer present.

The invention ensures safe drainage of liquid, in particular rain water, from the film layer, advantageously in the event of a collapse of the film layer, in a structurally simple but effective manner. According to the invention, this is achieved by using a valve whose valve element closes the relevant opening in the membrane layer in the normal operating state and has to withstand only the load caused by the wind and, in the case of a membrane mat, also the pressure inside the mat. Furthermore, according to the invention, the valve element and the opening and closing member are designed such that the valve in the closed state is likewise able to withstand a column of water up to a defined height, which defines the above-mentioned threshold value. If the water column exceeds a defined height, the load of the water column will cause the valve to open by pivoting the valve element from the closed first position to the open second position. It can be said that the pressure of the liquid acting on the valve element leads to an automatic pivoting of the first valve element from the first position into the second position, since gravity acts not only on the valve element itself but also on the liquid acting on the valve element, as a result of which the valve element is pressed downward. By means of the subsequently opened valve, the liquid which has accumulated on the upper side of the film layer, in particular in the collapsed state, is reliably drained, as a result of which the water column falls. In order to ensure that the water can be discharged substantially completely, according to the invention the valve is pivoted from the open second position back into the closed first position only in the substantial absence of a water column by pivoting of the operating element actively caused by the opening and closing member according to the invention, for which purpose the opening and closing members are correspondingly designed according to the invention such that they can effect this return pivoting movement only by overcoming the weight of the valve element.

The design according to the invention has other advantages as well. Since the valve element is arranged pivotably according to the invention, it is possible to open the valve element such that the opening is substantially completely released; this enables a relatively high flow rate of the liquid to be discharged, so that the discharge of liquid from the relevant film layer can be completed in a relatively short time. Other advantages include significantly improved reliability, lower manufacturing costs, and lower maintenance costs.

The device according to the invention can be implemented on a single-layer membrane roofing system or a membrane roofing system, wherein the first membrane layer forms the only membrane layer. Alternatively, the device according to the invention can also be used on a film mat, the cavity of which is bounded not only by the first film layer but also by the second film layer. In the case of a membrane mat, in the event of a malfunction, liquids, in particular rain water, can accumulate not only on the upper side of the upper membrane layer, but additionally or alternatively also on the upper side of the lower membrane layer. This is especially the case when the upper membrane layer collapses and the valve in the upper membrane layer is thus opened to expel the liquid. Subsequently, the liquid reaches the upper side of the lower film layer. In order to finally drain off the liquid from the lower film layer, the device according to the invention should preferably also be arranged in the lower film layer. In a preferred embodiment for a membrane mat, therefore, not only the first valve element and the first opening and closing member arrangement according to the invention are provided on the first membrane layer, but additionally also the second valve element and the second opening and closing member according to the invention are provided on the second membrane layer. This design can thus ensure that the membrane mat is completely cleaned of undesired liquid accumulations.

Further preferred embodiments of the invention are defined in the dependent claims 3 to 16, wherein the features, although essentially relating to the first film layer, the first opening formed therein, the first valve element and/or the first opening and closing element, are additionally related to the second film layer, the second opening formed therein, the second valve element and/or the second opening and closing element (in this connection also without distinction between "first" and "second") when the device according to the invention is used in a film mat according to claim 2.

The valve element is preferably designed as a flexible or elastic pressure plate, one end of which can be fixed to the film layer and the other end of which can be moved relative to the opening; and in one embodiment it is at least partially made of a film material, as a result of which a particularly simple construction can be achieved.

Alternatively, according to a further preferred embodiment, the valve element is designed as a flap, one end of which can be pivoted about a hinge that is mounted substantially fixedly with respect to the film layer and the other end of which can be moved with respect to the opening, and which, in one embodiment, forms a substantially rigid element. The use of the shutter has the advantages that: the corresponding opening in the membrane layer can be opened particularly effectively and in the second open position of the valve element substantially the entire opening cross section of this opening is exposed; and can be used to quickly and efficiently drain liquids.

Preferably, the opening and closing member has a resetting member which generates a resetting force to pivot the valve element from the second position in the direction of the first position.

In a development of this embodiment, the restoring element has a spring mechanism, the spring force of which forms the restoring force. When using a flap as the valve element, a particularly simple design development is possible, in which the spring mechanism has at least one helical spring which is arranged in the region of the hinge or on the hinge.

The magnitude of the resetting force generated by the resetting member may be determined such that the valve element is held in the first position as long as the pressure of the liquid exerted on the valve element is less than or at most equal to a threshold value, so that when the threshold value is exceeded, the resetting force is overcome and the resetting member is thereby made to yield, thereby opening in the valve element and reaching the second position.

A further preferred embodiment of the invention is characterized in that the opening and closing member has a first magnet element which can be mounted on and/or in the membrane layer and a second magnet element which is arranged on and/or in the valve element, wherein the two magnet elements are aligned with one another and are designed to generate an attractive force which acts on the two magnet elements. This attractive force pivots the valve element to the first position and also ensures that the valve element is held in the first position to close the associated opening in the film layer. In this context, it is also to be pointed out for the sake of completeness that the term "magnet" used in the claims encompasses different forms, wherein, for example, a plate-shaped body is preferably used as the magnet element, or alternatively a magnetic material is used or a magnetizable material is used as the magnet element, for example by coating or adding it.

The suction force is therefore preferably determined such that the valve element is brought into the first position and held in the first position if and as long as the pressure of the liquid exerted on the valve element is less than or at most equal to the threshold value.

Furthermore, the attractive force is preferably determined such that the valve element is brought into the first position if the distance between the two magnet elements is below a predetermined maximum value.

After the liquid has been substantially completely discharged in the second position of the valve element, i.e. in its substantially fully opened position, the valve element is no longer subjected to the liquid pressure. Thus, there is no hydraulic pressure opposing the valve element from pivoting from the second position back to the first position. Instead, only the weight of the valve element needs to be overcome for this pivoting movement. In a preferred embodiment of the aforementioned embodiment, the restoring force of the restoring element is therefore dimensioned such that it can pivot the valve element from the second position in the direction of the first position substantially only by overcoming the weight of the valve element. The distance between the two magnet elements inevitably becomes smaller and smaller if the valve element approaches the first position, i.e. the closed position, during the pivoting movement. As a result, the distance between the two magnet elements is below the mentioned predetermined maximum value, after which the attractive force between the two magnet elements starts to act and thus is responsible for the remaining pivotal movement of the valve element into the first position. After all, the return pivoting movement of the valve element from the second position to the first position is caused firstly by the resetting force of the resetting member and then by the attractive force between the two magnet elements. The combined use of the restoring force of the restoring element first and the attracting force of the two magnet elements then makes it possible to carry out the pivoting movement of the valve element from the second position into the first position in a particularly structurally simple and at the same time very effective manner.

Alternatively, (1) the first solenoid valve may have a magnetic material and the second magnet element may have a magnetizable material, or (2) the first magnet element may have a magnetizable material and the second magnet element may have a magnetic material, or (3) both magnet elements may have a magnetic material.

The second magnet element is preferably arranged in the region of or adjacent to the other end of the valve element, which end is remote from or opposite the end of the valve element for pivotable fastening to the membrane layer.

Drawings

The present invention will be described in detail below based on preferred embodiments. Wherein:

FIG. 1 schematically illustrates in cross-section a membrane mat of a building envelope having a valve according to a preferred embodiment of the present invention disposed in each of two membrane layers defining the membrane mat;

fig. 2 shows a detail of one of the two film layers of the film mat according to fig. 1 in a detail view and schematically shows the structure of the valve in the following positions: (a) in a closed first position, in which water is located on the upper side of the film layer, (b) in a substantially fully open second position, (c) in a pivoted position during the pivoting movement from the open second position to the closed first position, and (d) again in the closed first position, in which the film layer is free of water and therefore no water is loaded onto the film layer.

Fig. 3 shows schematically in cross section the situation of the membrane mat according to fig. 1 in the following state: (a) in the first state, the upper membrane layer begins to collapse and water is formed on the upper membrane layer, but both valves are still closed, (b) in the second state, the upper membrane layer partially collapses, more water is formed on the upper membrane layer, and both valves are now open, so water has reached the lower membrane layer;

fig. 4 schematically shows in cross-section the membrane mat in the following state: (a) in the first state, the upper membrane layer is fully collapsed and water is formed on the upper membrane layer, but both valves are still closed, (b) in the second state, more water has accumulated on the fully collapsed upper membrane layer and both valves are now open, so water has reached the lower membrane layer and is drained through the valves in the lower membrane layer;

fig. 5 shows schematically in cross-section the membrane mat in the following state: (a) in the first state, the upper film layer is still substantially completely collapsed, now there is relatively little water on the upper film layer, the two valves are closed again and compressed air starts to be blown into the film mat, (b) in the second state, already more compressed air is blown into the film mat to raise the upper film layer and the valves are still closed; and

fig. 6 schematically shows in cross-section a membrane mat in the following state: (a) in the first state, the upper film layer has been torn, whereby the valves in the upper film layer have failed and water has accumulated on the lower film layer, but the valves in the lower film layer are still closed, (b) in the second state, more water has accumulated on the lower film layer, and the valves in the lower film layer are now opened to drain the water.

DETAILED DESCRIPTION OF EMBODIMENT (S) OF INVENTION

In fig. 1 a building envelope in the form of a membrane mat 2 is schematically shown in cross-section, which may be used together with a number of further building envelopes or membrane mats to form a membrane roofing system or a membrane roofing system. In the illustrated embodiment, the membrane mat 2 is defined by an upper membrane layer 4 and a lower membrane layer 6. The film layers 4, 6 are welded to each other along their edges 8 and fixed to the carrier structure 10. A substantially fluid-tight cavity 12 is formed between the two film layers 4, 6. The cavity 12 is filled with compressed air, for which purpose, in the embodiment shown, a compressed air supply line 14 communicates with the cavity 12, which compressed air supply line is connected to a compressed air supply device, not shown, and is guided through the lower film layer 6. Further, an upper first valve 20a is provided in the upper membrane layer 4, and a lower second valve 20b is provided in the lower membrane layer 6. These two valves 20a, 20b serve to drain the water accumulating on the upper side of the respective film layer 4 or 6, which water is here usually rain water, as will be explained in more detail below.

In the embodiment shown, the two valves 20a, 20b have the same structure, which is schematically shown in fig. 2. As can be seen in fig. 2, the valves 20a, 20b on the film layers 4 or 6 are each arranged in the region of an opening 22, which opening 22 is formed in the respective film layer 4 and 6 and is defined by opposite edge portions 24a, 24b of the film layer 4 or 6, respectively. Furthermore, the valves 20a, 20b each have a valve element 26, which in the illustrated embodiment is designed as a substantially rigid flap and which is arranged pivotably at one end 26a via a hinge 28 on the adjacent edge 24a of the film layer 4 or 6, so that the valve element 26 can be moved with the other end 26b opposite the end 26a relative to the other edge 24b of the film layer 4 or 6. A spring 30, which is preferably designed as a helical spring and biases the valve element 26 into a closed first position, in which the valve element 26 is shown in fig. 2a, is also arranged in the region of the hinge 28. For this purpose, essentially only the spring force of the spring 30 is determined such that it counteracts the dead weight of the valve element 26.

A first magnet 32 is arranged on the other edge portion 24b of the thin- film layer 4 or 6. In the embodiment shown, the first magnet 32 is designed as a plate-like body which is arranged flat beside or on the edge portion 24b of the film layer 4 or 6. Alternatively, however, it is also conceivable, for example, to mold the first magnet 32 in the edge portion 24b of the film layer 4 or 6 and thus in the film layer 4 or 6, or to provide the edge portion 24b or a part of this edge portion 24b with a magnetic or magnetizable material, for example by coating or introducing a magnetic or magnetizable material. All of the foregoing embodiments, as well as other correspondingly suitable, non-mentioned embodiments, are herein equally ascribed to the term "magnet" as used herein. As a counterpart magnet, the second magnet 34 is arranged on the other end 26b of the valve element 26 opposite the end 26a and the hinge 28, so that the second magnet 34 lies adjacent to the first magnet 32 on the edge portion 24b of the film layer 4 or 6 in the closed first position of the valve element 26, as shown in fig. 2a, or even contacts the first magnet. Similarly to the first magnet 32, in the exemplary embodiment shown, the second magnet 34 is also designed as a plate-shaped body made of a magnetic or magnetizable material. Instead of being arranged next to or on the valve element 26, it is also conceivable, for example, to mold the second magnet 34 into the other end 26b of the valve element 26, or to provide the other end 26b of the valve element 26 with a magnetic or magnetizable material, for example to coat or introduce a magnetic or magnetizable material. The two magnets 32, 34 preferably have a magnetic material; alternatively, it is also conceivable for the first magnet 32 to have a magnetic material and the second magnet 34 to have a magnetizable material, or conversely for the first magnet 32 to have a magnetizable material and the second magnet 34 to have a magnetic material. The two magnets 32, 34 are aligned with each other so that they generate a magnetic force that attracts each other. The suction force thus generated ensures that the valve element 26 is held in the closed first position according to fig. 2a and thus forms a locking force. In normal operating conditions, the valve element 26 only has to withstand the load from the wind and, in the case of the membrane mat 2, as shown in fig. 1, also the air pressure prevailing in the cavity 12 of the membrane mat 2.

In certain generally undesirable situations, which will be discussed in more detail later, water, particularly rain water, may accumulate on the upper side of at least one of the two film layers 4 or 6, generally first on the upper side of the upper film 4 as shown in fig. 1. The same applies to the case of the use of single-layer membrane roofing systems or membrane roofing systems, in which, in contrast to the membrane mats shown in fig. 1, only the membrane layer 4 is used here as the sole membrane layer. This state is schematically illustrated in fig. 2a, in which the water 40 collected by the film layer 4 or 6 and the valve element 26 is schematically illustrated at a distance on the top side, wherein the arrows 40a symbolize the water column by which the water 40 presses on the film layer 4 or 6 and the valve element 26. Thus, the valve element 26 is loaded with a load from the water column 40 a. The water column 40a may be maintained at a defined height above the valve element 26. The attractive forces of the two magnets 32, 34 are determined such that the valve element 26 remains in the closed first position if and as long as the valve element 26 is loaded with a pressure corresponding to the height of the water column 40a and which is less than or at most equal to a predetermined threshold value. Of course, the attractive force and thus the locking force can be varied by the strength of the magnets 32, 34.

As the water 40 increases further, the water column 40a rises. If the water column exceeds a defined height corresponding to the above defined threshold, the attractive force of the magnets 32, 34 is overcome, causing the valve element 26 to be opened in the direction of arrow A to an open second position against the spring force of the spring 30. In this case, the valve element 26 is tilted downward such that the open second position is located below the closed first position, as shown in fig. 2 b. Thus, the pivoting of the valve element 26 into the lower, closed second position is caused by the water pressure. As can be seen in fig. 2b, the valve element 26 in its open second position releases a substantially complete cross section of the opening 22 in the film layer 4 or 6, so that the opening 22 is substantially completely exposed. As a result, the water 40 can flow in the direction of the arrow a at a high flow rate, and thus quickly pass through the opening 22, and thus can be discharged.

After the water has been substantially completely drained, the valve element 26 is no longer loaded with water pressure. Thus, no water pressure prevents valve element 26 from pivoting from the open second position back to the closed first position. This pivoting movement therefore only has to overcome the weight of the valve element 26. As previously mentioned, the spring force of the spring 30 is thus determined such that it substantially counteracts only the weight of the valve element 26 and thus the effect of the weight on the valve element 26 to pivot the valve element from the open second position in the direction of the closed first position, which is indicated by arrow B in fig. 2 c. The spring force of the spring 30 is therefore relatively small, so that it cannot prevent the valve element 26 from opening and thus from pivoting into the open second position shown in fig. 2b as a result of the water pressure, but rather is pressed against it, so to speak.

In fig. 2c, the valve element 26 is now shown in the pivoted position during the pivoting movement from the open second position to the closed first position. The distance between the two magnets 32, 34 also inevitably becomes smaller and smaller as the valve element 26 approaches the closed first position during the pivoting movement caused by the spring 30. As a result, the distance between the two magnets 32, 34 is below a predetermined maximum value, so that the attractive force between the two magnets 32, 34 then comes into play and takes over the remaining pivoting movement of the valve element 26 into the closed first position. The return pivoting movement of the valve element 26 from the open second position to the closed first position is therefore caused firstly by the spring force of the spring 30 and then by the attractive force between the two magnets 32, 34.

Fig. 2d again shows the valve element 26 in the closed first position, in which the membrane layer 4 or 6 is now free of water, so that in the normal operating state neither the membrane layer 4 or 6 nor the valve element 26 is loaded with water pressure.

Fig. 3 to 6 show exemplary different embodiments of the membrane mat 2 shown in fig. 1, in which the use of valves 20a, 20b plays a role.

Fig. 3 shows the case where the upper film layer 4 is partially collapsed. This is often due to minor leaks or faults in the compressed air supply. Here, as shown in fig. 3a, the strong wind load causes the upper film layer 4 to partially collapse and water 40 to accumulate there. In this state, both valves 20a, 20b are still closed. Fig. 3a shows a state where the upper film layer 4 has just begun to collapse and water 40 has formed on the upper side of the upper film layer 4, while fig. 3b shows a subsequent state where the upper film layer 4 is now more severely collapsed and more water 40 has formed on the upper film layer 4. This causes the upper valve 20a to open, thereby draining water 40 onto the lower membrane layer 6. Thus, not only the lower membrane layer 6, but also the lower valve 20b arranged there is loaded with an elevated water pressure. This in turn causes the lower valve 20b to also open and thus drain the water 40 outwards until the collapsed membrane mat 2 is substantially completely free of water.

If desired, the two valves 20a, 20b can be selectively set at the same or different thresholds at which the attractive forces of the magnets 32, 34 are overcome and the valve element 26 is pivoted from the upper closed first position to the lower open second position (see fig. 2), which in principle can be applied to all situations and embodiments and thus also to other situations described below with reference to fig. 4 to 6.

Fig. 4 shows a situation in which the upper membrane layer 4 is essentially completely collapsed, more precisely because the pressure is essentially completely lost and may additionally be influenced by strong wind loads. Fig. 4a shows the following states: that is, the upper membrane layer 4 has completely collapsed, and water 40 has thus formed on the upper membrane layer 4, but both valves 20a, 20b are still closed. Fig. 4b shows a subsequent state: that is, more water 40 has accumulated on the completely collapsed upper membrane layer 4 and, as a result of the water pressure rising, not only the upper valve 20a is opened, but also the lower valve 20b is opened at the same time, since now the water pressure also acts with a similar or identical intensity on the lower valve 20b via the collapsed upper membrane layer 4.

Fig. 5 illustrates, by way of example, the process of restoring the initially collapsed film mat by blowing in fresh compressed air, and thereby returning the upper film layer 4 from the collapsed position below to the normal operating position above, where the upper film layer 4 again has the upwardly curved shape shown in fig. 1. Fig. 5a depicts a first state in which the upper film layer 4, although substantially completely collapsed, has only relatively little water 40 still present on the upper film layer 4, so that now both valves 20a, 20b are closed again and compressed air begins to be blown into the film mat. Fig. 5b shows a subsequent state in which further compressed air has been blown into the film mat 2 to raise the upper film layer 4, of course with the valves 20a, 20b still closed. Although a small trough-like portion remains initially in the upper film layer 4 during this recovery process, in which the remaining water 40 still accumulates, this trough-like portion disappears as the module inflates into the film mat 2, whereby the remaining water 40 still there is discharged laterally.

Finally, in fig. 6, another situation is shown, in which the upper film layer 4 is torn due to the very high wind load, whereby the lower film layer 6 is exposed upwards and outwards like a trough. The torn upper film layer 4 can now no longer retain or take up rainwater; instead, the water 40 reaches directly to the upper side of the lower membrane layer 6 and accumulates there. The upper valve 20a is deactivated because the upper film layer 4 is in a torn state. Figure 6a shows a first condition in which the upper film layer 4 has torn so that the upper valve 20a has failed and water 40 has accumulated on the lower film layer 6, but the lower valve 20b is still closed because the water pressure is not yet sufficient. Fig. 6b shows a subsequent state in which more water 40 has accumulated on the lower membrane layer 6, and now due to the rise of the water pressure, the lower valve 20b is opened in order to drain the water 40 downwards by gravity.