DE10333113B3 - Fall prevention device for protection of worker on flat roof has bearing plate with projecting post provided with fastening element for safety line at its top end - Google Patents

Abstract

The fall prevention device (1) has a post (5) projecting from a bearing plate (3) located between the flat roof and the roof covering layer (2), provided at its top, which projects above the latter, with a fastening element for securing a safety line for a roof worker (7). The bearing plate is secured to a load bearing layer (8) below the roof covering layer, for distribution of the load resulting from a fall.

Description

The The invention relates to fall protection and a fall protection system for roofs with ballast as well as their use on green or roofs covered with slabs or gravel roofs.

fall Protection and fall arrest system are designed to prevent people from falling off roofs or other high areas prevent. For those who enter regularly roofs become frequent railing fixed on the roof. For roofs that don't have regular traffic and only occasionally, for example for maintenance work must be entered by people, the expensive railings are often dispensed with. Instead fall protection in the form of breakpoints or ropes or temporary railings provided on the roof.

Temporarily on the Railings erected on the roof usually have vertical railing posts with angled, foot struts resting on the roof covering. With the known railings these footsteps weighed down by transportable weights, for example sandbags. The weight the railing and the weights are to be chosen so large that they have a sufficiently large weight have to crash one on the railing hanging To prevent person. A disadvantage of these temporary railings is however, the extraordinary size Installation effort. So must the bulky components and the heavy counterweights laboriously the roof to be transported. There are also additional ones during the erection of the railings Fall protection measures for the meet people working on the roof. Another disadvantage is the high purchase price of the railings.

Usually are therefore for irregularly entered roofs Fall protection devices are provided that remain permanently on the roof. In their simplest form, these are fall protection devices only simple breakpoints, such as on the roof structure attached eyelets. At these stops you can who do on the roof A safety line, for example with the help of a snap hook, Fasten. The people usually wear safety harnesses or a shoulder strap, on which in turn is also referred to as a safety line Safety line is attached.

at roofs, which is a gravel fill or a green roof have fall protections are common where the fastener for the Safety line at the end of one attached to the roof substructure Post is attached. This has the advantage that the posts are over the gravel layer or vegetation layer protrude and the fastener easier to find.

This the last-mentioned fall protection devices remain permanently on the Roof, must not cumbersome can be assembled and disassembled and are cheaper to buy as a railing. However, a disadvantage of these known fall protection systems is that that they're basically anchored in the roof substructure or attached to roof elements Need to become. As a rule, therefore, posts and support mechanisms are already in the Planning phase of the roof depending the roof substructure and the necessary fasteners selected, fixed and measured. For this, the substructure however, be suitable for fastening such fall protection devices and have a certain minimum tensile strength. This increases the planning Effort and reduces flexibility in the choice of posts and Fasteners as well as the roof substructure or the supporting structure. An afterthought Attaching such a fall protection is, if at all, only with big Effort possible because the roof seal is used to find tension-resistant fastening points are at least partially included in the substructure got to. The attachment to the underground is still very expensive and expensive.

On another great The disadvantage of these known fall protection devices is that they must be passed through the roof membrane for fastening. This is particularly disadvantageous because such breakthroughs are difficult to seal and are therefore always weak points in the Waterproofing the roofs against moisture and cold represent. The penetration of the roof skin often occurs to leaks and cold bridges that severely affect the effectiveness of the roof sealing systems can.

In order to introduce the forces acting on the person to be secured or the fall protection in the event of a fall as gently as possible, elaborate suspension mechanisms are attached to the known posts or to the suspension lines. These dampen the jerky force and thus reduce the load on both the person being caught and the system due to the dynamic fall load initiated. Each individual fall arrest device has a circular working area with its individual attachment point. In order to cover the required work area, several fall protection devices are set up relatively close together and mounted so that they are spaced from the edge of the roof in such a way that a fall with the correct length of the suspension line not possible. The distance to the roof edge is usually 2 m to 4 m. Such an arrangement requires a fairly large number of fall protection devices and is therefore relatively expensive. In addition, there is a risk to personnel due to incorrect or improper use of safety ropes of different lengths and the frequent need to change the anchor points.

task The invention is therefore a fall protection and a fall protection system for roofs with Roof load indicate which the roof sealing is not in their Impair function, yourself afterwards can be installed on finished roofs without interfering with the roof substructure, are safe and comfortable to use and inexpensive to manufacture can be.

The solution this task is accomplished with fall protection according to claim 1 and the fall protection system according to claim 14. In addition, the Task by using the fall protection according to the invention or the Fall protection system according to claim 21 solved. Preferred embodiments and further developments are described in the subclaims.

The Fall protection according to the invention for roofs with Roof load comprises a support surface and one connected to it Post. The post protrudes a surface the contact surface before and points in a remote from the support surface and over the Roof load projecting section on a fastener. This fastener is used to secure one against falling to be protected Crash load. The fall protection also has a load-bearing layer on that as a base for at least part of the roof load is determined. The load bearing layer is with the contact surface connected, protrudes laterally the contact surface above and is dimensioned in such a way that the fall protection applied to the roof load holds the falling load acting on the fastener.

According to the Fall load to be secured only through a cooperation of the Fall protection according to the invention held with the roof load, without any other attachment done on the roof structure. In particular, it is no longer necessary, to anchor the fall protection in the substructure. A damage roof sealing is therefore excluded, cold spots or leaks do not arise. Moreover is a retrofit already finished roofs without big Effort possible because the roof load is only temporarily removed in some places, the fall protection according to the invention the roof area set up and the roof load over the fall protection must be reapplied. As a counterweight for the Crash load is the one that already exists or is already provided Dachauflast. The for the fall protection needed additional Components and interventions in the roof structure can be done with it be kept to a minimum.

The The roof load can consist of a gravel fill, a slab covering, For example, from washed concrete or paving stones, a green roof or Components of the same or similar exist. As a roof load of course also Combinations of the loads mentioned serve. To find the To facilitate fastener of the fall protection stands the upper end of the post after applying the roof load over it before, and the fastener is in an upper section of the post, appropriately so, that it is also about the roof load protrudes, is not overwhelmed by the load or overgrown by plants becomes.

Under the fall load that is secured by the fall protection is mainly one Understand person with their weight load. The forces that must be picked up and held by the fall protection system determined by the intended application and are usually in relevant Norms and regulations. In order to prevent that a leashed person over the roof edge falls, will fall protection according to the invention appropriately spaced set up from the roof edge. Should, contrary to expectations, become one Fall protection must be able to prevent the fall to catch and hold a person falling from the roof on a leash. According to this crash load or according to any legal requirements The fall protection according to the invention is specified sized. However, it should be noted that this does not mean that the fall protection in any case remain stationary under the influence of the fall force got to. Certain shifts in the fall protection on the roof in Towards the crashing Loads are quite permissible and sometimes even desirable to cushion the fall. critical is that fall protection is timely and within any given Limits the crash load holds and carries.

In the fall protection system according to the invention, the fall load is first passed over the post into the support surface attached to the lower end of the post. This distributes and transfers the fall load across the entire area to the load bearing layer. The load-bearing layer serves to accommodate a roof load or at least part of the roof load. The type and size of the load bearing layer are dependent on the fall load to be absorbed on the one hand and the type and weight of the roof load coming to rest on the load bearing layer on the other hand, chosen so that the fall load acting on the fall protection loaded with the roof load is held securely.

ever heavier that on a unit area the lower the superimposed roof load, the lower can the area the load-bearing layer. Conversely, one only does low roof load per unit area requires a larger load bearing layer, to be able to carry a given fall load to be secured. More at the design of the load bearing layer to be taken into account, but less important factors include the surface properties of the load-bearing layer and roof load. The slipperier one or both of the materials, i.e., the lower the friction between the two, the greater should be the area the load-bearing layer. A tight interlocking of the load bearing layer with the overlying substrate or the substrate is not necessary. Rather, the holding force of the fall protection essentially results from the frictional forces between the load bearing layer, roof load and also the roof area and is therefore predominant depending on the weight of the load and the nature of the friction contact surfaces. This allows it also, the fall protection afterwards, without cumbersome after Having to look for attachment points and anchored to a roof without perforating the roof waterproofing.

The for the Fall protection according to the invention components used consist of weatherproof materials, that can withstand the expected loads in the long term. suitable Materials are, for example, corrosion-resistant metals and weather-resistant plastics. As a support surface, the basically serves to fix the post suitable flat Materials such as steel mesh, mesh, etc. Especially plate-like materials, for example metal and especially steel plates. The invention will follow on Example of a plate described as a support surface, without therefore on limited such to be. Some of the components used, such as posts and fasteners are already available in state of the art fall arrest systems and can are also used accordingly in the context of the invention.

The Posts can be attached to the slab in various ways. A possibility is a permanent, non-removable Fastening, for example by welding. However, it is more convenient to use the post solvable to be connected to the plate, for example by releasable fastening means such as screws, plug connections, snap or snap connections, bayonet-like Connections or the like. In an advantageous embodiment, the post is not rigid, but has a joint or a spring that at least one Allow movement in the direction of the attacking fall load. Thus, the post of the fall load can be flexibly around a defined one Give in measure and dissipate the force braked into the anchoring system. Make it possible the joint or the spring deflects the post in the direction of the roof edge or the fall load and reduce due to the Deflection the distance between the load application point and the rotating pole fall protection. So it becomes the lever arm of the mechanical System impact load reduced. This increases the stability of the fall protection stressful torques from the fall load are effectively reduced or prevented. In other words, the one removed from the crash load lying part of the plate is not or only reduced from the floor lifted. At the same time enables in particular the spring-loaded post introduces dynamic force the fall load on the fall protection. This reduces the one jerky impact on the impact of the falling person.

In a particularly preferred embodiment becomes a break around the joint or the spring when deformed Sleeve on pushed the post. This sleeve protects first once the joint or the spring from contamination, while still Spring or joint preferably above the vegetation layer or Roof load are arranged. On the other hand, the sleeve is through the deformation of the post in the joint or spring area under the action a crash load deformed to break or at least severely and has clearly visible deformations. Visible from this deformed or broken sleeve it can then be determined that fall protection is a greater burden was exposed and their functionality and security should be checked. After review or Repairing the fall protection will be appropriate sleeves again via the Joint or over the spring pushed onto the post. An intact, undeformed sleeve shows the operational readiness of fall protection.

In a further preferred embodiment, the post is designed such that it has a visible deformation after being loaded by the fall load. This also enables a damping load transfer of the fall load into the fall protection, reduces the leverage effect of the post and visualizes, in analogy to the sleeve described above, a previous load caused by a fall load. A combination of a deformable post with an articulation and a breaking sleeve is also advantageous, since this further increases the damping and also for this ensures that the most heavily loaded components of the fall protection system are replaced after each load.

It has also proven to be useful in that the fastener located on the post is designed so that there is a visible deformation after loading from the fall load having. this makes possible also a damping Load initiation and a visualization of previous loads. When designing the deformation properties of both the post as well as the fastener is of course to ensure that this deform to such an extent only under the load, than this does not lead to breakage of the component in question. In Regarding the fastener, it is also advantageous if only parts of the fastener visibly deform plastically or if the fastener has a seal, which under the crash load breaks.

The Posts such as the fastening element or the plate can basically be made of any material that is suitable for outdoor use and withstands the relevant loads. Preferably there are Post, the fastener and the plate made of a metal such as steel. However, are also conceivable accordingly suitable plastics, such as glass fiber reinforced plastic or hard rubber, such as in the case of a deformable post. Furthermore can Parts of the fall protection according to the invention, which are also already used in fall protection systems of the prior art Have found application, in principle correspond to the known parts.

In another development of the invention are on the side of the plate protruding support elements attached to tilt or move the plate as possible to prevent. It is particularly advantageous, at least three sides of the plate over such support elements support. Have as appropriate outriggers here proven that are intended to rest on the roof surface. Advantageous is at least one lateral support element towards the roof edge aligned, and all support elements are usually useful with regular same angle to each other the plate in front to evenly prevent the plate from tipping on all sides to back up.

For one if possible uniform, flat introduction the crash load in the load bearing layer is, as already explained above with the plate of the crash element connected. The connection is made preferably about Needles over the surface protrude the plate. The load bearing layer is used for fastening pressed onto the needles or claws and so tearproof connected to the plate. It is particularly advantageous here if the power transmission through a Variety of if possible finely and closely spaced needles. This ensures a good one Claws a more even power transmission and reduces the individual voltage peaks at the power transmission points in the load bearing layer. The load suspension layer can do the same also by means of screws, preferably with washers are provided on the surface the plate. It is also advantageous to use the load bearing layer, if necessary additionally to another type of fastening, with the help of an adhesive to fix the plate. The adhesive should at least weatherproof but often also UV-resistant his.

As It has proven advantageous to place the load-bearing layer between the plate and another plate attached to it. To the two plates are screwed together, for example. It is advantageous to have one of the two panels already in the workshop or in the production with a fastening system such as the screws so that when installing the fall protection the corresponding plate, for example the counter plate, only loosely must be placed on the ground. Then the load-bearing layer is above spread out, which advantageously already with perforations is provided for pushing through the fasteners. After that the plate with the post attached to it and then using nuts on the protruding screws of the counter plate be screwed and clamped. After that, go to the load bearing layer a defined roof load, for example a layer of gravel, plant substrate or other bulk goods or a plate surface applied.

The The load-bearing layer can basically be made up any suitable flat Material. Tear-resistant, weather-resistant fabrics are preferred, Sheets or nonwovens, such as those, albeit for a different purpose, partially already as protection, insulation or sealing layers on roofs were used. The load-bearing layer preferably consists of a fleece. In particular, it is a needled Fleece, which is particularly tear-resistant and the usual Minimum durability requirements met. However, it is also possible for one corresponding enlargement of the Disk surface for example on a base area of more than 5 m × 5 m, on particularly tear-resistant fleece to waive as long as certain minimum strength requirements and durability are. For the tear strength and durability the same applies to foils or fabrics.

In in any case, it is advantageous if the load-bearing layer has a certain elasticity having. this leads to to an expansion of the fall protection in the area of the load bearing layer and corresponding jerk-free load initiation. The positive The effect of resilient posts in the flexible load suspension can supported in this way become.

Especially It is advantageous if the load-bearing layer is within one layer of the layer structure of a green roof. Fleece protection layers are common in green roof structures arranged as a protective layer of the roof waterproofing. If the plate of Fall protection according to the invention attached directly to the layer of the roof structure, this results a particularly simple and inexpensive embodiment, since the load-bearing layer a double function as part of the layer structure of the green roof and as part of the fall protection system. This reduces the weight which has to be carried by the roof, the effort in the production and the cost. Since such roof layers are usually over the entire of the green roof covered area extend, is the bearing surface practically always big enough to keep a falling load safe.

A similar one A synergy effect is achieved if the load-bearing layer is a drainage element. Drainage elements are on roofs usually flat on the roof surface designed to form a water-draining layer. they are coming both on gravel roofs on green as well roofs for use. In their simplest form, they consist of plates or sheets of water-conducting material with fiber, random lay-up, Flake, lattice or nub structure. Drainage elements are also known with perforated base plate and storage troughs or water storage Foams to absorb excess water. Likewise, and is particularly suitable as a load-bearing layer one by the applicant in German patent application No. 10330318.9 described drainage element for delayed water drainage. at Use of drainage elements as a load bearing layer is too note that the drainage element is either as large and it is difficult that with the roof load that is on it, one enough size Holding force to effectively prevent a fall, or but that several adjacent drainage elements are tensile are connected to each other and thus form a flat load bearing layer, enough for one huge Can absorb part of the roof ballast to effectively prevent a crash prevent.

Several, in particular several set up at a distance along the roof edge Fall protection devices according to the invention form a fall protection system. Form in a manner known per se The fall arrest anchor points that are attached to the roof can fix existing workers with their safety lines. there the fall protection devices are placed on the roof in such a way that it for the working people is possible to move on the fall arrest lines on the roof edge. It is advantageous if the around the respective post or Overlap the circular work area resulting in the fastener. It is important, however, that the individual fall protection devices are installed in relation to the roof edge are positioned at a distance from the edge so that the working people no over can crash the roof out. This means that the maximum working radius of a fall protection system defines the minimum distance to the roof edge, the corresponding Regulations must be observed.

In a preferred embodiment are the plates of the individual fall protection devices in a fall protection system connected to a common load bearing layer. This has the advantage that only a single load bearing layer is brought onto the roof must be in order to form a fall protection system. Especially It is advantageous if the load-bearing layer is already part of the Green roofs is. The latter extends over the entire roof area, the load bearing layer absorbs the entire roof load, which is for example from the green roof results. this makes possible the greatest possible holding force of the fall protection system.

In a particularly preferred embodiment, a safety rope is tensioned on the fastening elements from support posts to support posts between adjacent fall protection devices. The safety rope is used to attach the safety line and forms a linear rope system. It is advantageous if the safety line can be moved along the safety rope. This enables the fall-proof persons on the roof to move particularly well, since they no longer have to be leashed at specific points. A safety line with a snap hook or a similar device, which can be easily pushed along on the safety rope, is therefore preferably used for the leash. With the safety rope tied parallel to the roof edge, it is possible to move and work parallel to the roof edge. It is particularly advantageous if the safety rope runs 20 cm to 50 cm above the roof load. This enables good work even below the safety line, especially when mowing, prevents the safety cable from overgrowing on a green roof, or prevents the safety cable from becoming dirty. It also serves to make it easier to find the safety rope, especially with be green and overgrown roofs. In case of doubt, the height to be selected at which the safety rope is attached to the post results from the expected height of vegetation and the layer thickness of the roof load.

at Using a safety rope should be noted that a Slipping of the safety rope on the fasteners is prevented, as this becomes an undesirable Extension of crash length to lead would. A correspondingly effective fastening means are rope clips, which the fasteners on the posts for mounting of the safety rope.

Especially a fall protection system is preferred and advantageous, in which lateral support elements are designed as cross struts, which adjacent plates rigid connect with each other. This creates a solid substructure, the one flat stability against horizontal shear and tensile forces and capable is the forces introduced by the posts from above the green roof horizontal rope tensioning. It is advantageous if the posts have sufficient stability to support the rope of the safety rope between the posts without being able to that the posts deform. This can be a problem especially in green areas smooth rope run on the tensioned safety or guide rope respectively. Due to the rigid connection, the fuse or guide rope acting crash forces introduced into adjacent posts, even to more distant ones Posts forwarded and absorbed by the rigid overall system. The fall protection system is therefore more resilient than the single fall protection. Analogously, this also applies to the recording of tensile forces at corner points.

In a further embodiment is on the ends of the side support elements facing the roof edge a railing attached to the fall protection system. This is so far advantageous than the fall protection of a group of people and it is no longer necessary the people working on the roof put on safety harnesses allow. This increases the freedom of movement during the work and especially then suitable if longer term or longer ongoing work is to be expected, which increases the effort required to set up of a railing can be suitable. The railing can only be temporary be attached to dismantled after use is complete to become. Unlike in the prior art, this is without much effort and possible without interfering with the roof waterproofing. The fall protection system according to the invention is therefore special in terms of its applicability and possible uses flexible.

The Use of the fall protection according to the invention or the fall protection system according to the invention is particularly preferred on green roofs, flat roofs or Roofs with low inclination, which are loaded with a layer of gravel, or on roofs, those with slabs such as concrete roof tiles, washed concrete blocks or are also covered with paving stones of a general kind.

The The invention is explained in more detail below with reference to a drawing. In this show schematically:

1 a first embodiment of a fall protection according to the invention in a perspective exploded view;

2 the section AA through the in 1 shown part of the roof and fall protection according to the invention;

3 a cross section through a second embodiment of the fall protection according to the invention;

4 a post with a joint of a fall protection according to the invention according to a third embodiment;

5 a post with a spring of a fall protection according to the invention according to a fourth embodiment;

6 a post with a sleeve of a fall protection according to the invention according to a fifth embodiment;

7 a post with a deformed sleeve of a fall protection according to the invention according to a sixth embodiment;

8th a post with a visible deformation of a fall protection according to the invention according to a seventh embodiment;

9 an eighth embodiment of the fall arrest device with a counter plate fastened by screws for fastening the load-bearing layer in an exploded view;

10 a ninth embodiment of the fall protection with two rectangular plates and side support elements;

11 a plan view of a roof with a fall protection system according to the invention;

12 the cut BB through the in 11 Fall protection system shown and

13 a second embodiment of a fall protection system with a railing.

1 shows schematically a first embodiment of a fall protection according to the invention 1 , On a roof waterproofing 24 a plate lies loosely 13 , on their surface 4 a post 5 is welded on. At the top of the post 5 is a fastener 6 arranged. In the embodiment shown here is the fastener 6 an eyelet into which a person holds the fall load to be protected against falling 7 represents a lanyard 19 can attach. On the surface 4 the plate 3 are a series of fastening pins pointing upwards 13 appropriate. On the needles 13 becomes a load-bearing layer 8th pressed so that the load bearing layer 8th then with the plate 3 is firmly clawed. The load bearing layer 8th is a flexible and elastic fleece in this embodiment, which laterally over the plate 3 survives and as a base for a roof load consisting of a layer of gravel 2 serves. The fleece works 8th also as a protective layer of the roof waterproofing 24 by preventing pointed objects from being pressed into the roof waterproofing.

2 shows the section AA through the in 1 Fall protection shown 1 , The person to be protected against falling 7 does work on the roof near the edge of the roof 23 and is by means of a lanyard 19 about the fastener 6 with fall protection 1 connected. The length of the leash 19 is to be dimensioned according to the relevant regulations. Here is the length of the line 19 chosen so that the person 7 not over the roof edge 23 can reach out.

Fall protection 1 is in this representation in the installed state for the most part under the gravel fill 2 , This layer stretches across the load bearing layer 8th out so that the load bearing layer 8th only part of the total roof load 2 receives. This part of the fill 2 is so heavy that a crashed person as a crash load 7 which in the event of a crash on the eyelet 6 of the post 5 hangs, is held. According to current regulations, it is not necessary that fall protection 1 when the fall load acts 7 remains stationary on the roof. Fall protection 1 may move up to 1 m towards the roof edge before catching the person. In the case shown, there can be a shift from the flexible and elastic nonwoven layer 8th take place, which is under the fall load 7 stretches and the fall of the person 7 attenuates.

The post 5 is rigid with the plate in this embodiment 3 connected. The plate 3 again lies loosely on the roof waterproofing 24 on, this above a thermal insulation 25 on the roof support structure 26 is arranged. So no components of the fall protection penetrate 1 the roof waterproofing 24 or the thermal insulation 25 , This is of great advantage, since it ensures the tightness of the roof waterproofing 24 is not destroyed and no cold bridges are formed.

In 3 is a second embodiment of fall protection 1 shown the total roof load shown 2 with the load bearing layer 8th receives. The roof load 2 in this exemplary embodiment contains a plant substrate fill for a green roof. The load bearing layer 8th consists of loose on the roof waterproofing 24 on top and with a root protection fleece 37 covered drainage elements connected to each other with tensile strength 16 , Also includes the roof load 2 a record path 27 from washed concrete blocks or pavement slabs. The post 5 is in this embodiment via a screw 31 detachable, but rigid with the plate 3 connected. On the plate 3 are lateral support elements 12 via fastening screws 14 , which is also the fastening of the load bearing layer 8th on the plate 3 serve, connected. It is advantageous in this exemplary embodiment that the load-bearing layer is thus at the same time part of the layer structure of the green roof. This saves costs and reduces the manufacturing costs of the fall protection or green roof.

4 shows a post 5 a third embodiment of the fall protection 1 , It points to a plate 3 welded posts 5 a joint 9 on. The joint 9 is so high on the post that it is above the roof load layer 2 lies and is not polluted by this or is impaired in its mobility. The joint 9 connects the rigid lower part 35 with the movable upper part 34 of the post 5 and enables the upper part 34 to deflect towards the roof edge, not shown.

5 shows a post 5 a fourth embodiment of the fall protection 1 where a feather 10 between the upper part 34 and the lower part 35 of the post 5 is arranged. That feather 10 enables the upper part to be pivoted 34 for example in the direction of the roof edge. This deflection ensures a yielding and thus dynamic load introduction of the crash load, not shown here 7 which on the fastener 6 is initiated in the fall protection. This suddenly leads to the post 5 attacking fall load 7 with a time delay and not suddenly in the fall protection 1 is initiated. This protects both the person to be secured or the fall load and the components of the fall protection.

In 6 is a post 5 a fifth embodiment of the fall protection 1 shown at which over a joint 9 or a feather 10 a sleeve 11 is pushed. The post 5 is removable in this example and therefore interchangeable with the plate 3 connected. In this embodiment, the connection is made via a on the plate 3 attached post support element 36 , The post 5 is on the post receiving element 36 the bottom plate 3 pushed and using a locking pin 33 locked by the locking pin 33 through drilling the post 5 and the post receiving element 34 is pushed and locked there if necessary.

7 shows a post 5 a sixth embodiment of the fall protection 1 , by attacking a crash load 7 the upper part 34 of the post 5 is deflected. This makes the sleeve 11 broken. Through the broken sleeve 11 it becomes visible that the post 5 due to a crash load 7 has been charged. This succeeds due to the permanent destruction of the sleeve 11 even if the crash load 7 no longer attacks. Thus, it is immediately possible to recognize that the fall protection 1 must now be checked for functionality. The sleeve 11 is interchangeable on the post 5 pushed. After completing the check of the functionality of the fall protection 1 can get a broken sleeve off the post 5 be stripped off and replaced by a new sleeve 11 be replaced. If necessary, also the post 5 replaced what at in 6 variant shown is particularly simple. The new sleeve then documents the full operational capability of the fall arrest device in its unbroken condition 1 ,

8th shows a post 5 a seventh embodiment of the fall protection 1 , which is under load from the fall load 7 has visibly deformed. Even if the crash load 7 no longer on the post or on the fastening element 6 attacks, the visible deformation remains. In the embodiment shown here, the post is concerned 5 around a 12 mm thick steel rod, which is on the plate 3 is screwed on. It has sufficient initial strength to prevent it from being deformed by lighter loads. Under a higher crash load 7 but he gives in and bends. Because of the permanent deformation, it is possible, as in the exemplary embodiment described above, to recognize that this post 5 due to a crash load 7 was charged. Fall protection can in turn be used accordingly 1 checked for functionality, and after completing this work the deformed post 5 with a new, not bent post 5 replaced. This then signals the operational readiness of the fall protection system 1 , This exemplary embodiment also enables due to the deformability of the post 5 dynamic load initiation of the fall load 7 in the fall protection 1 ,

9 shows a plate 3 an eighth embodiment of fall protection 1 that have different holes 29 having. On the surface 4 is a post 5 attached, which is essentially the post of the 6 equivalent. At the top of the post 5 are a rope clamp 20 and two rope guides 28 appropriate. Below the plate 3 is a second record 15 to recognize the welded threaded bolts on their top 14a which has in the holes 29 the plate 3 can be introduced and inserted. On the threaded bolts 14a then become the nuts 14b put on and dressed. This makes it possible to between the plate 15 and the plate 3 in the installed state, the load-bearing layer - not shown here 8th to clamp and so on the plate 3 to fix.

10 shows a three-dimensional exploded view of a ninth embodiment of the fall protection according to the invention 1 , In this embodiment, the plate has 3 additionally four side support elements 12 on, the post 5 on the plate 3 and the counter plate underneath 15 using two lock nuts 31 is attached. The post points to this 5 an external thread at its lower end 30 on. So it is possible the post 5 with the two plates 3 and 15 to screw. At the top is a fastener 6 on the post 5 screwed. Below the counter plate 15 there are four side support elements 12 which by means of screws 14a and nuts 14b screwed to the two plates and the load-bearing layer. The bracing of the load-bearing layer, which is only shown in part here 8th between the plates 3 and 15 is also done with these screws 14a and 14b , which are each twice in the respective support element 12 are arranged. Due to the lateral support, this embodiment results in a very particularly stable substructure, with the lateral support elements 12 via a connector 32 a further fall protection, not shown, can be plugged in. Arranging several fall protection devices creates a fall protection system 17 ,

Another stiffening of the load bearing layer 8th (only shown here as a section) can be achieved by additionally connecting to the support elements 12 is attached. A clamp is used for attachment 38 that are above the load bearing layer 8th on the support element 12 is placed and screwed to it, so that the load-bearing layer between the support element 12 and clamp 38 is pinched. Even if this is not shown here, clamps can of course be present on all support elements and can also be used several times per support element.

11 shows a top view of a roof on which there is a fall protection system 17 located, here without load. The same parts are provided with the same reference numerals. The fall protection system 17 consists of several, with each other via cross struts 21 associated fall protection 1 , The cross braces 21 become, for example, two supporting elements fastened together 12 formed as in 10 have been described. In the embodiment shown here, the fall protection devices have 1 . 1' . 1'' square plates each 3 on. Below the square plates 3 is the load bearing layer 8th , In the embodiment shown here, the load-bearing layer is 8th a fleece, which is above the cross struts 21 and the support elements 12 is rolled out in web form. Above each individual support element 12 becomes such a strip of the load bearing layer 8th arranged. This ensures that the support elements from one above the load bearing layer 8th part of the roof load 2 be charged. The posts 5 neighboring fall protection devices 1 are secured by a safety rope 18 connected. The posts 5 are designed in the embodiment shown here so that they have a sufficient initial strength to the safety rope 18 to tighten taut without the post 5 bend. It is also possible that a single continuous rope is not used, but between the respective post 5 one new safety rope each 18 is used. Each of the posts therefore preferably points 5 a rope clamp 20 on.

12 shows the section BB through the in the 11 Fall protection system shown 17 , this time with roof load 2 , As already described, cross struts connect 21 the fall protections arranged side by side 1 . 1' and 1'' , In the embodiment shown here, the load-bearing layer extends 8th across the entire width of the roof and takes the load on the roof 2 , which is part of a green roof. The posts 5 . 5 ' and 5 '' protrude about 20 cm to 50 cm above the surface of the roof load 2 out. The safety rope expediently runs 18 at least about 20 cm above the surface of the roof load 2 , This allows a smooth rope run on the tensioned safety rope 18 take place without the rope run of a safety line being impeded by the vegetation or parts of the vegetation. The safety rope also hangs 18 not on the roof load 2 and is not excessively polluted.

Preferably, a known post-skipping rope runner system is used for fastening, which the use of the in 11 and 12 shown system allows without the in 1 and 2 shown seat belt must be released. This makes the system particularly easy and safe to use.

Is that from the load bearing layer 8th absorbed roof load 2 sufficiently large, can be at the ends of the side support elements facing the roof edge 12 a railing 22 be attached. In the in 13 illustrated embodiment, this is a removable post 5 from the plate 3 by loosening the locking pin 33 solved and by a lateral support element 12 , which is parallel to the roof level in the direction of the roof edge, not shown 23 extends, replaced. Above the support element 12 is a railing 22 appropriate. The ropes run between several railing supports 22 that on neighboring posts 5 a fall protection system 17 are attached.

Claims (21)

Fall protection ( 1 ) for roofs with a roof load ( 2 ), which has a contact surface ( 3 ) and one connected to it and over a surface ( 4 ) of the contact surface ( 3 ) protruding post ( 5 ), the post ( 5 ) in one of the contact surface ( 3 ) distant and over the roof load ( 2 ) projecting section a fastener ( 6 ) to secure a fall load to be protected against falling ( 7 ), characterized in that it is used as a base for at least part of the roof load ( 2 ) certain load bearing layer ( 8th ) with the support surface ( 3 ) is connected, protrudes laterally over it and is dimensioned such that it is connected to the roof load ( 2 ) applied fall protection ( 1 ) on the fastener ( 6 attacking fall load ( 7 ) holds. Fall protection according to claim 1, characterized in that the post ( 5 ) detachable with the contact surface ( 3 ) connected is. Fall protection according to claim 1 or 2, characterized in that the post ( 5 ) a joint ( 9 ) or a spring ( 10 ) having. Fall protection according to claim 3, characterized in that around the joint ( 9 ) or the spring ( 10 ) around a sleeve that breaks when deformed ( 11 ) on the post ( 5 ) is pushed. Fall protection according to one of the preceding claims, characterized in that the post ( 5 ) is designed in such a way that it is 7 ) has a visible deformation. Fall protection according to one of the preceding claims, characterized in that the fastening element ( 6 ) is designed so that after the load from the fall load ( 7 ) has a visible deformation. Fall protection system according to one of the preceding claims, characterized in that on the contact surface ( 3 ) lateral support elements ( 12 ), in particular on at least three sides over the contact surface ( 3 ) above support elements intended for resting on the roof surface are attached. Fall protection according to claim 7, characterized in that the load-bearing layer ( 8th ) with a fastening means, in particular with a to the support element ( 12 ) screwed clamp ( 38 ), on the support element ( 12 ) is attached. Fall protection according to one of the preceding claims, characterized in that the load-bearing layer ( 8th ) by means of the surface ( 4 ) of the contact surface ( 3 protruding needles ( 13 ), using screws ( 14 ) or with the help of an adhesive on the contact surface ( 3 ) is attached. Fall protection according to one of claims 1 to 9, characterized in that the load-bearing layer ( 8th ) between the contact surface ( 3 ) and a second support surface attached to it ( 15 ) is clamped. Fall protection according to one of the preceding claims, characterized in that the load-bearing layer ( 8th ) consists of a fleece, in particular a needled fleece, a film or a fabric. Fall protection according to claim 11, characterized in that the load-bearing layer ( 8th ) is a layer within the layer structure of a green roof, in particular a fleece protective layer. Fall protection according to one of claims 1 to 12, characterized in that the load-bearing layer ( 8th ) a drainage element ( 16 ), in particular a drainage element for delayed water drainage. Fall protection system ( 17 ), characterized in that there are several and in particular several with a distance along the roof edge ( 23 ) installed fall protection devices ( 1 . 1' . 1'' ) according to one of the preceding claims. Fall protection system according to claim 14, characterized in that the bearing surfaces ( 3 . 3 ' . 3 '' ) fall protection devices ( 1 . 1' . 1'' ) with a common load bearing layer ( 8th ) are connected. Fall protection system according to claim 14 or 15, characterized in that between adjacent fall protection devices ( 1 . 1' . 1'' ) a safety rope ( 18 ) for attaching a safety line ( 19 ) on the fasteners ( 6 . 6 ' . 6 '' ) of posts ( 5 ) to post ( 5 ' . 5 '' ) is excited. Fall protection system according to claim 16, characterized in that the safety rope ( 18 ) 20 cm to 50 cm above the roof load ( 2 ) runs. Fall protection system according to claims 15 or 16, characterized in that the fastening elements ( 6 . 6 ' . 6 " ) Rope clamps ( 20 ) to hold the safety rope ( 18 ) exhibit. Fall protection system according to one of the preceding claims, characterized in that lateral support elements ( 12 ) as cross struts ( 21 . 21 ' ) are formed, the adjacent contact surfaces ( 3 . 3 ' ) rigidly interconnect. Fall protection system according to one of the preceding claims, characterized in that on the ends facing the roof edge, lateral support elements ( 12 ) a railing ( 22 ) is attached. Use of fall protection or fall protection system according to one of the preceding claims on green roofs, gravel roofs or with contact surfaces occupied roofs.