BE1027274B1 - MOBILE SYSTEM SUITABLE FOR DEMOLITION WORK - Google Patents

Abstract

The invention is in the field of demolition works. In particular, the invention provides a mobile system for demolition works. The invention also relates to a method for delineating demolition works.

Description

MOBILE SYSTEM SUITABLE FOR DEMOLITION WORK

TECHNICAL FIELD The invention is in the field of demolition works. In particular, the invention provides a mobile system suitable for demolition works. The invention also relates to a method for delineating demolition works. And others such as temporary shoring in case of fire, earthquakes, explosions and natural disasters.

TECHNOLOGICAL BACKGROUND OF THE INVENTION The terms demolition, demolition or demolition refer to the breaking down of a movable or immovable property into smaller components that can then be disposed of. Demolition works are preferably carried out by means of (heavy) vehicles such as a demolition crane or wrecking ball, which mechanically break down the building structures to be demolished.

In urban and industrial areas, however, the demolition sector is confronted with sites in which mechanical demolition cannot be carried out. Within a residential core there is usually a lack of space to place the necessary machinery as well as to properly collect falling debris. As a result, it is often decided to manually demolish the building structures. This typically takes place by building a scaffolding against the building construction to be demolished, which can then be demolished manually (row by row) by workers.

However, manual breakdown is an inefficient, expensive and risky way. Manual dismantling is often also associated with a greater risk of accidents, since everything has to be done on a smaller surface. The hazard concerns falling or collapsing a building, falling debris and exposure to harmful substances such as asbestos and quartz dust.

Moreover, placing a scaffold also requires that the scaffolding must be anchored to the construction to be demolished. After all, the position is not reliable and depends on the wind. This creates an additional risk. Due to an outdated state of walls, larger pieces can suddenly come loose during demolition, causing the scaffolding to fall down. Workers who are currently on the scaffolding therefore run an additional risk. Anchoring to the wall at height is also problematic if the same wall has to be demolished.

Building and dismantling a scaffold is also very labor-intensive. Scaffolding is also susceptible to accidents: for example, when a (demolition) crane collides with the scaffolding, a pipe can fold, making the entire scaffolding unstable. As a result, the demolition of building structures is dangerous and specialist work. Traditionally, the demolition sector scores worse in terms of accidents at work than the average construction sector as a whole. More concretely, this means that the frequency rate is worse, but also the severity rate. Studies show, for example, that for the year 2009 in the Belgian construction sector there were a total of 22 work accidents with fatal consequences for an employment of 154,200 FTEs (1 per 7,000 FTEs). In the demolition sector, this was 2 fatal accidents per 5,000 FTEs, or 1 per 2,500 FTEs for the same period. There is therefore a need for a system that offers a solution to one or more of the foregoing problems.

SUMMARY The present invention and its preferred embodiments aim to provide a solution to one or more of the aforementioned drawbacks. To this end, the present invention relates to a mobile system for demolishing a building construction. The invention also provides a method for demolishing a building structure.

In a first aspect, the invention relates to a mobile system suitable for demolition works, the mobile system comprising: - a container with extendable support elements; - an inflatable screen arranged in the container; and, - at least two conductors for guiding the inflatable screen.

In some preferred embodiments, the inflatable screen includes an inflatable cushion. In some preferred embodiments, the screen is made of PVC.

In some preferred embodiments, the inflatable screen is provided with a friction-reducing and / or crack-reducing coating. In some preferred embodiments, the system includes a screen blowing agent; preferably an air pump. In some preferred embodiments, the screen includes an overpressure protection means. In some preferred embodiments, the screen is attached to the guides. In some preferred embodiments, the conductors have a maximum adjustable height of at least 1.0 m to at most 50.0 m.

In some preferred embodiments, the guides include drive means; preferably an electric or hydraulic drive. In some preferred embodiments, the support members have a length of at least 1.0 m to at most 3.0 m. In some preferred embodiments, the support members are support legs.

In some preferred embodiments, the system includes a stabilizer. In some preferred embodiments, the system includes a nebulizer installation. In some preferred embodiments, the system includes noise reduction means. In some preferred embodiments, the at least two guides are extendable and / or expandable. In a further aspect, the invention relates to a method for delineating a demolition site, the method comprising the steps of: (a) placing a mobile system as described herein, preferably near a demolition site; (b) placing the extendable support elements in a support position; (c) unfolding a guide, preferably the two guides;

(d) adjusting the height of an inflatable screen, preferably by means of a beam or bar; and, (e) inflating the inflatable screen. In some preferred embodiments, the height of the inflated screen is gradually lowered so that the demolition work on the one hand and the screen on the other are at approximately the same height.

In a further aspect, the invention relates to a method of decommissioning the mobile system as described herein, the method comprising the steps of: (a) deflating an inflatable screen; (b) rolling up or folding the inflatable screen in the container; (c) putting down and putting away the guides in the container; (d) putting the extendable support elements in or against the container; and, (e) optionally, sealing the container.

In some preferred embodiments, the mobile system is carried by a means of transportation.

In a further aspect, the invention relates to a use of a mobile system as described herein for delineating a demolition job.

Such a mobile system partly solves the above problems of classical theorems.

Such a mobile system also has the advantage that it can be slid on, so that only smaller surfaces are required. By systematically moving up the mobile system as the demolition works progress, its use saves materials and costs. Such a mobile system also has the advantage that it can be easily transported and / or moved, requiring fewer vehicles.

Such a mobile system is also efficient: no street needs to be closed or traffic stopped. The mobile system ensures less dust, less loose lumps. The mobile system avoids the need for a mounting crane. The mobile system is more resistant to wind, for example wind forces up to 8 Beaufort.

DESCRIPTION OF THE FIGURES In order to better demonstrate the features of the invention, some preferred embodiments of the present invention have been described in the accompanying figures without any limitation. The numerical references are discussed in more detail in the examples. The following numbering is used throughout the figures, claims and examples: 100 - mobile system; 110 - container; 120 - support elements; 130 - inflatable screen; 140 - conductors. Figure 1 shows a schematic representation of part of a mobile system according to a preferred embodiment. The inventors have discovered that the mobile system as described herein can offer the following advantages: improved security conditions, such as: no more need to build and finish scaffolds break; and / or, - it is no longer necessary to work with an inflatable; - dust control; and / or, - faster degradation options. This container makes it possible to mechanically demolish walls that actually have to be demolished manually, because the container provides a closed safety screen so that falling debris cannot end up outside the work zone. Furthermore, it is no longer necessary to build a scaffolding along the wall to be demolished, and employees no longer need to be sent on the scaffolding to demolish the wall row by row.

As demolition progresses, the inflated screen can in some embodiments be rolled up gradually (divided into compartments that can be individually vented) so that the wall to be demolished on the one hand and the bumper on the other hand are always at the same height.

In addition, when placing a traditional scaffolding, it is also the case that the scaffolding must be anchored in the wall to be demolished.

This creates an additional risk.

Due to an outdated state of walls, larger pieces can suddenly come loose during demolition, so that the scaffolding falls down when this piece of wall comes down.

Employees who are breaking down a wall on a scaffolding therefore run an additional risk that can now be excluded with the container.

The container is not anchored in the wall and nobody has to stand on top of it to be able to carry out the demolition.

There is also no need for a bouncy castle or mat.

The unstable and cumbersome existing principle consists of creating a rubber jumping mat (+ 120m? With a weight of 4 tons).

When lifting the jumping mat, which is only attached at the top, it can catch a lot of wind and that can cause adverse situations.

The entire process takes a lot of energy and effort to ensure that everything runs smoothly.

Because the curtain "hangs" loosely, as it were, and does not completely adjoin the building, there is a risk that large fragments will push the jumping mat in the wrong direction uncontrollably.

The container solves this problem because, in contrast to the jumping mat, it is brought close to the wall to be demolished.

The pillow is inflated until it is against the wall and thus provides a slight counter pressure.

For example, the debris will always fall to the inside of the work zone and the problem with falling debris on, for example, public roads is significantly reduced.

An additional problem when working with a jumping mat is the fact that it has to be placed upwards on a construction site, which means that one must again opt to break down using a scaffolding.

Since environmental legislation also requires that dust control is carried out during demolition work, one usually opts for a nebulizer that reduces the dust faster and also makes the soil moist.

Here, the container also offers a solution in the sense that the inflatable cushion ensures that it is completely closed just behind the wall to be demolished.

This gives the same effect as with a scaffolding around which a screen has been hung.

However, the container also saves the work that must be carried out to hang these guards on built-up racks.

By carrying out a breakdown with the container, employees are also no longer exposed to dust.

After all, when dismantling from a scaffolding, one is constantly exposed to dust, especially if the scaffolding is also closed with tarpaulins to prevent the dust from spreading outside the work zone.

Due to the fact that no more scaffolding has to be built, less dust control and less personnel have to be provided, the user can assume that demolition can be realized faster and cheaper and that, moreover, far fewer processes need to be carried out logistically. The cushion container actually replaces the scaffolding and shielding and significantly less preparation time is required before starting the actual demolition work.

DETAILED DESCRIPTION Before describing the present system and method of the invention, it is to be understood that this invention is not limited to the specific systems and methods or combinations described, as such systems and methods and combinations may of course vary. It should also be understood that the terminology used herein is not intended to be limiting, as the scope of the present invention is limited only by the appended claims.

All documents cited in the current specification are fully incorporated herein by reference.

As used further in this text, the singular forms “a”, “the”, “it” include both the singular and the plural unless the context is clearly different. The terms "include", "includes" as further used are synonymous with "include", "include" or "include," include "and are inclusive or open and do not exclude additional, unspecified members, elements or process steps. The terms “comprise”, “comprises” include the term “contain”.

The listing of numeric values by a range of numbers includes all values and fractions in these ranges as well as the quoted endpoints.

The term "about", as used when referring to a measurable value such as a parameter, an amount, a time duration, etc., is intended to include variations of +/- 10% or less, preferably +/- 5% or less, more preferably +/- 1% or less, and more preferably +/- 0.1% or less, of and from the specified value, as far as the variations are applicable to function in the disclosed invention .

It is to be understood that the value to which the term “approximately” refers in itself was also disclosed.

Various aspects of the invention are further defined in the following passages.

Any aspect so defined can be combined with another aspect or aspects, unless clearly stated to the contrary. In particular, a feature referred to as the "preferred" or "advantageous" may be combined with other features or properties referred to as "preferred" and / or "advantageous". Reference in this specification to "one embodiment" or "an embodiment" means that a particular function, structure, or feature described in connection with the embodiment is applicable in at least one embodiment of the present invention. When the phrases "in one embodiment" or "an embodiment" appear at different points in this specification, they do not necessarily refer to the same embodiment, although this is not excluded. Furthermore, the described features, structures or characteristics may be combined in any suitable manner, as will be apparent to one of ordinary skill in the art based on this description. The described and claimed embodiments can be used in any combination. In the present description of the invention, reference is made to the accompanying drawings which form a part thereof and which illustrate specific embodiments of the invention. Numbers in brackets or in bold linked to certain elements illustrate the relevant elements as an example, without limiting the elements. It is to be understood that other embodiments can be used and structural or logical changes made without departing from the scope of the present invention. The following detailed description is not to be construed as limiting, and the scope of the present invention is defined by the appended claims.

Unless defined otherwise, all terms disclosed in the invention, including technical and scientific terms, have the meaning as commonly understood by one of skill in the art. As further guidance, definitions are included for further explanation of terms used in the description of the invention.

Demolition as used herein refers to a structure such as movable or immovable property that is to be demolished or demolished. The mobile system described herein is not limited to any particular demolition method or device. It is understood that the current demolition method is particularly suitable for demolition by means of

(heavy) vehicles such as a wrecking crane or wrecking ball that create a large amount of trapped debris and / or dust.

The demolition work will typically be on a construction site.

Construction site as used herein refers to a site on which construction is in progress or suitable for construction.

A construction site therefore also refers to a construction site, building site or construction site.

The invention relates in a first aspect to a mobile system for demolition works, the mobile system comprising - a container with extendable support elements; - an inflatable screen arranged in the container; and, - at least two conductors for guiding the inflatable screen.

The mobile system has two forms.

In a first transportable form, the screen, the support elements and the at least two guides are arranged in or against the container.

In the first form, the size of the mobile system is hereby limited to the container, which can be easily transported and moved by means of a means of transport such as a truck.

The container has the size of a typical freight container; for example a 20 feet container or a 40 feet container.

A 20 foot container typically has an internal length of 5.9 meters and a volume of 33.2 m2. A 40 foot container typically has an internal length of 12.03 meters and a volume of 67.7 m °. Preferably, the container has an external length of minimum 5 meters to maximum 25 meters, for instance from minimum 6 meters to maximum 15 meters.

The container preferably has an external height of a minimum of 2 meters to a maximum of 25 meters, for instance from a minimum of 2.5 meters to a maximum of 5 meters.

When the mobile system is placed near a demolition work, such as on a construction site, it can be converted into a second static form.

Preferably, the extendable support elements are first removed from the container.

These support elements ensure that the system remains stable and cannot slide.

These support elements also ensure that the container can be leveled, for example on uneven terrain.

Then the height of the guides can optionally be adjusted to the desired height; the desired height will typically correspond to the height of the demolition work, such as a wall to be demolished.

The screen will show the height of the conductors (partially)

to take over.

The screen can be pulled up together with the guides, or it can be pulled up after the guides are set.

The guides are preferably extendable and / or foldable, more preferably foldable.

Finally, the screen can be inflated to form a safety screen suitable for collecting falling demolition, such as part of a building, falling debris and / or fine dust.

Preferably, the conductors are first unfolded, then the screen is pulled up, and then the screen is inflated.

As demolition progresses, the height of the inflated screen can be gradually reduced so that the construction to be demolished on the one hand and the screen on the other are always at the same height.

The support elements are preferably hydraulically controlled.

In some embodiments there are adjustable differential pressures, for example 2 or 3 adjustable differential pressures on the pad.

This allows the cushion to drop, for example over a distance of 1 meter.

Then the pressure can be increased again.

The screen preferably comprises valves and / or pressure relief valves to control the whole in height and / or to roll up the whole.

In some embodiments, the screen includes different sectors.

Letting the air out of one or more sectors can cause the screen to drop.

In the second form, the mobile system essentially forms a closed space so that falling debris and / or dust cannot end up outside the demolition zone.

This makes it possible to mechanically demolish walls that actually have to be demolished manually.

This also eliminates the need to build scaffolding along the structures to be demolished.

There is therefore no need to place employees on the scaffolding to manually demolish the construction (row by row). Moreover, it is not necessary to anchor the mobile system to the structure, so there is no risk of collapsing walls or scaffolding.

The fully erected construction can have an area of at least 10 m? and cover a maximum of 675 m ”, preferably at least 15 m? and a maximum of 500 m ”, for example a minimum of 20 m? and a maximum of 200 m ”, for example a minimum of 30 m? and a maximum of 100 m ”, for example a minimum of 40 m? and a maximum of 60 m °. The container itself is maintenance-friendly.

Preferably, the mechanical parts of the container are accessible, for example to enable removal of dust and stones.

In some embodiments, the container includes one or more doors, for example on the sides of the container.

Preferably, the mobile system comprises 4 support elements, preferably on each corner of the container.

The support elements preferably provide a wider surface.

This gives a stable container.

The support elements serve to support the mobile system on the ground.

The support elements can optionally be anchored.

Anchoring elements will typically use anchoring elements (e.g. screws, anchor points, and the like). The support elements can be manually extended and attached, or can extend mechanically, for example with the aid of an electrical or hydraulic system.

The support elements are preferably support legs.

The support elements are preferably made of a metal; such as steel.

The support elements have a height of preferably minimum 0.2 m to maximum 2.0 m, for instance from 0.4 m to 1.6 m, for instance from 0.8 m to 1.2 m.

The support elements preferably have a width that is less than or equal to the width of the container.

In some embodiments, the support members are staggered.

This ensures that they can be pushed in compactly.

In some embodiments, a support member has a length of at least 1.0 m to at most 3.0 m.

The length of the support element is defined as the distance from one end of the support element to the second end of the support element.

The length of a support element can optionally be adjustable; in that case, the maximum length is determined when the support element is fully extended.

The guide guides the inflatable screen to the desired height and then serves to support the screen on the container.

The guide is preferably anchored or attached to the container.

The conductor includes a body, which is preferably a single, continuous unit.

Alternatively, the conductor can be of modular construction, whereby a series of bodies are connected together.

The conductor is preferably made of a metal; such as steel.

In some embodiments, the at least two guides are extendable and / or collapsible, more preferably collapsible.

In some embodiments, the guide can be manually adjusted in height, for example, by an extension system.

Preferably, the height of the guide is adjusted mechanically, for instance with the aid of an electrical or hydraulic system.

Preferably, the mobile system comprises at least two height-adjustable guides for guiding the inflatable screen. The use of two conductors makes it possible to strengthen the edges of the screen better. The more conductors that are provided, the stronger the screen can be reinforced, but also the more expensive the system becomes. The use of two conductors provides an optimal balance between strength and cost.

In some embodiments, the guide has a maximum adjustable height of at least 1.0 m to a maximum of 50.0 m. The maximum height of the guide member is defined as the distance from one end of the guide to the second end of the guide when the guide is fully extended or folded out, preferably folded out. In some embodiments, the system also includes cables and / or rods, which provide additional strength. This ensures good tension between two folding guides. The deflated (i.e., uninflated) screen fits into the container. The screen will preferably be folded or rolled up. This makes it possible to move the system quickly and easily to another construction site. The screen is preferably wear-resistant, tear-resistant, and / or replaceable. In some embodiments, the system includes a beam or rod configured to raise the top of the screen. This beam or rod can also be raised along the guides, for example by means of wheels in a profile. The inflated screen preferably forms a safety screen or safety pad for collecting debris and / or dust. It is understood that the screen is therefore suitable for collecting debris without causing (significant) damage; it is preferably made of a material that will not break or tear on contact with falling debris. The screen is preferably made of polymer, preferably PVC, preferably UV resistant PVC. The thickness of the inflated screen is preferably a minimum of 40 cm and a maximum of 120 cm, preferably a minimum of 60 cm and a maximum of 100 cm, for example about 80 cm. These materials are suitable for avoiding cracks when collecting stones or metal debris. The screen can be provided with a friction-reducing and / or crack-reducing coating. The screen may include an inflatable cushion. By providing a separate inflation space inside the screen, the risk of cracks is further reduced. The inflatable screen preferably comprises an inflatable cushion, preferably an inflatable and rollable cushion, against which are along one (preferably the outside)

cloths are attached.

These cloths are preferably tear resistant and / or replaceable.

These cloths can be attached to the cushion, for example, via Velcro (velcro).

The system preferably includes means for inflating the screen; a screen blowing agent.

This can be, for example, an air pressure pump or compressor.

The pump preferably has a low pressure (preferably adjustable) and a high flow rate, like the pump for an air castle.

Once inflated, the screen is preferably kept at a constant air pressure.

This is possible by providing a continuous supply of an air flow; for example by means of fans.

Alternatively, this may be possible by making the screen completely airtight so that no air can escape; for example by means of valves.

The screen is preferably provided with an overpressure protection means; preferably a buckling system.

If the screen were to hit something, such as the breakdown tap, it could burst.

The screen is attached to the guide.

Preferably the screen is connected to the guide by means of a guide system.

In some embodiments, the guide system includes wheels in a profile.

The screen can be attached to the wheels, preferably in a removable way.

This ensures that the screen can be easily replaced.

The confirmation can be temporary or permanent.

The advantage of a permanent attachment is that the screen can be immediately brought to the desired height.

The advantage of a temporary connection is that the screen can be disconnected so that the guide can be adjusted first and the screen can be pulled up afterwards.

A temporary connection also makes it possible to arrange the guide and the screen more compactly in the container.

The inflated screen is also sometimes referred to herein as a "safety cushion" or "pad".

In some embodiments, the safety pad is divided into compartments that can be individually vented.

This allows it to be rolled in gradually so that the wall to be demolished on the one hand and the safety cushion on the other are always at the same height.

In some embodiments, the screen includes a multi-channel system that leads directly to the different compartments.

These channels can be structurally processed on the inside of the safety cushion and consist of the same material.

Each compartment can then be vented separately by means of an air valve.

In some embodiments, the screen automatically slides down during the breakdown.

In some embodiments, the pad includes a multi-channel system that leads directly to the different compartments.

These channels can be structurally processed on the inside of the fender and consist of the same material.

Each compartment can then be vented separately, for example by means of an air valve.

In some embodiments, the inflated screen is convex. This ensures that there is no gap when two containers are next to each other.

The system can be provided with a means for noise reduction, for example cloths. This makes the system extremely suitable for demolition in urban spaces with strict noise standards.

The system may be provided with a stabilizer. This would allow it to stabilize the screen in strong wind and / or rainfall.

The system may be provided with a misting system. By spraying fine water (mist), the amount of small dust in the air can be limited or even prevented. Preferably, this misting system is placed in a top bar or rod that pulls the screen along. Spray heads can be placed in or on this beam or bar. Optionally, there is also a misting system on the sides. This can be placed on the guides. Preferably, the connection with water is provided at the bottom, for instance in or on the container. The container optionally includes a water reservoir.

In a further aspect, the invention relates to a method for delimiting a demolition work. The mobile container as described above comprises a mechanism for this purpose that offers the possibility of rolling out a safety cushion against a wall to be broken down.

The container is preferably placed along the wall to be demolished, after which the, not yet inflated, safety cushion can be rolled out upwards by means of a simple control system. This can be done with great precision so that the system can be used optimally. Once the safety cushion has been rolled out, it can be inflated up to the wall to provide a certain amount of counter pressure.

Preferably, the container is placed on the construction site by means of a truck, for instance at approximately 80 cm from the wall to be demolished. The support elements, preferably extendable legs, are brought into position; once the container has been placed, it can still be moved (for example up to a maximum of 1 meter) in the direction of the wall to be demolished.

Then, preferably two guides come out of the container via a hydraulic system. The roll-up screen is pulled upwards via these two guides to the required height (for example, the height of the wall to be demolished). Finally, the cushion attached to the screen is inflated (for example, in different compartments) until it contacts the wall, creating a slight back pressure. During the breakdown, the screen gradually slides back down. In some embodiments, the method comprises the steps of: (a) deploying a mobile system according to one or more embodiments as described herein, preferably near a demolition site; (b) placing the extendable support elements in a support position; (c) unfolding a guide, preferably the two guides; (d) adjusting the height of an inflatable screen, preferably by means of a beam or bar; and, (e) inflating the inflatable screen.

Preferably the inflatable screen is rolled out against a wall to be broken down. The container is placed along the wall to be demolished, after which the, not yet inflated, inflatable screen can be rolled out upwards by means of a simple control system. This can be done with great precision so that the system can be used optimally. Once the inflatable screen has been rolled out, it can be inflated up to the wall to provide a certain amount of counter pressure.

The container is preferably placed on site at a distance from the wall to be demolished. This distance is preferably minimum 10 cm and maximum 150 cm, for example minimum 20 cm and maximum 140 cm, for example minimum 40 cm and maximum 120 cm, for example minimum 60 cm and maximum 100 cm, for example approximately 80 cm. brought as support elements. Then, preferably two guides come out of the container via a hydraulic system. The roll-up screen is pulled upwards via these two guides to the required height (= height of the wall to be demolished). Finally, the pad attached to the screen is preferably inflated until it makes contact with the wall, providing a slight back pressure. For example, the debris will always fall to the inside of the work zone and the problem with falling debris on, for example, public roads is significantly reduced. The maximum installation time is preferably 1 hour, for example 45 minutes, for example 30 minutes, for example 15 minutes. This is considerably faster than traditional scaffolding.

In some embodiments, the screen automatically slides down during the breakdown. As a demolition progresses, the safety cushion can be rolled in gradually (for example divided into compartments that can be individually vented) so that the wall to be demolished on the one hand and the safety cushion on the other are always at the same height.

The invention in a further aspect relates to a method for winding down the mobile system, the method comprising the steps of: (a) deflating an inflatable screen; (b) rolling up or folding the inflatable screen in the container; (c) putting down and putting away the guides in the container; (d) putting the extendable support elements in or against the container; and, (e) optionally, sealing the container. Once completed, the mobile system can be transported or moved by a means of transport, such as a truck with the aid of a crane. The invention in a further aspect relates to a use of a mobile system according to one or more embodiments as described herein for delineating a demolition work. In addition to specific situations in demolition work, the mobile system can find a useful application, for example, for unloading boats with a lot of dust (unloading earth or wood) and / or demarcating events with noise pollution. The mobile system can therefore also be used for loading and / or unloading ships. Alternatively, the mobile system can be used to prevent noise nuisance, for example at elements. The mobile system is preferably used to prevent dust nuisance.

Preferably, the maximum duration for placing and setting up the container is a maximum duration of 30 minutes.

Traditional scaffolding takes up an area of 140 m? took about eight hours.

Preferably, the maximum time for retracting the cushion is a maximum time of 15 minutes compared to 4 hours in traditional scaffolding.

Preferably, the container can withstand gusts of wind up to 8 Beaufort (wind load is measured on the top of the container via an anemometer and / or electronic sensors). If the limit is exceeded, the fender can be lowered to an acceptable level.

Preferably, the container is stable on an unpaved and / or sloping (for instance up to a slope of 5 degrees) surface, whereby the container can function in a fully functional manner.

The support elements absorb variations and slopes in the subsoil.

Preferably, the container can autonomously bridge a lateral displacement, for instance with a maximum distance of 1 meter. The support elements make such a lateral displacement possible.

Preferably, the container is able to maintain dust development within the zone of the container.

A misting installation can take care of this.

Preferably, the bumper is fully protected against falling objects from the building to be demolished (stone rubble, glass, steel). This can be provided by the use of a replaceable protective cloth.

The container preferably creates a physically closed zone between the public environment and the work zone, as opposed to placing the traditional scaffolding with dusters.

Preferably the construction and operation of the container is done by only a limited number of persons, for example by 1 person specifically trained for this purpose, and this preferably from the ground floor.

EXAMPLES Reference is made to the figures by way of example.

The embodiments illustrated in the figures are preferred embodiments of the present invention and should in no way be construed as limiting.

Example 1 Figure 1 shows a schematic representation of a system according to an embodiment of the invention.

Claims (20)

CONCLUSIONS A mobile system (100) suitable for demolition works, the mobile system (100) comprising: - a container (110) with extendable support elements (120); - an inflatable screen (130) arranged in the container (110); and, - at least two guides (140) for guiding the inflatable screen (130). The mobile system (100) of claim 1, wherein the inflatable screen (130) comprises an inflatable cushion. The mobile system (100) of any of claims 1 or 2, wherein the screen (130) is made of PVC. The mobile system (100) of any of claims 1 to 3, wherein the inflatable screen (130) has a friction and / or crack reducing coating. The mobile system (100) of any of claims 1 to 4, wherein the system (100) comprises a screen inflator; preferably an air pump. The mobile system (100) of any one of claims 1 to 5, wherein the screen (130) includes overpressure protection means. The mobile system (100) of any of claims 1 to 6, wherein the screen (130) is attached to the conductors (140). The mobile system (100) of any of claims 1 to 7, wherein the conductors (140) have a maximum adjustable height of at least 1.0 m to at most 50.0 m. The mobile system (100) according to any one of claims 1 to 8, wherein the conductors (140) include drive means; preferably an electric or hydraulic drive. The mobile system (100) of any of claims 1 to 9, wherein the support elements (120) have a length of at least 1.0 m to at most 3.0 m. The mobile system (100) of any of claims 1 to 10, wherein the support elements (120) are support legs. The mobile system (100) of any of claims 1 to 11, wherein the system (100) comprises a stabilizer. The mobile system (100) of any one of claims 1 to 12, wherein the system (100) comprises a nebuliser. The mobile system (100) according to any one of claims 1 to 13, wherein the system (100) includes noise limiting means. The mobile system (100) of any of claims 1 to 14, wherein the at least two guides (140) are extendable and / or expandable. A method of delineating a demolition site, the method comprising the steps of: (a) placing a mobile system (100) according to any one of claims 1 to 15, preferably near a demolition site; (b) placing the extendable support elements (120) in a support position; (c) deploying a guide, preferably the two guides (140); (d) height adjustment of an inflatable screen (130), preferably by means of a beam or bar; and, (e) inflating the inflatable screen (130). The method of claim 16, wherein the height of the inflated screen (130) is gradually lowered so that the demolition work on the one hand and the screen (130) on the other are at approximately the same height. A method of decommissioning the mobile system (100) according to any of claims 1 to 15, the method comprising the steps of: (a) deflating an inflatable screen (130); (b) rolling up or folding the inflatable screen (130) into the container (110); (c) lowering and setting the guides (140) in the container (110); (d) depositing the extendable support members (120) in or against the container (110); and, (e) optionally, closing the container (110). The method of claim 18, wherein the mobile system (100) is carried by a transportation means. A use of mobile system (100) according to any one of claims 1 to 15 for delineating a demolition job.