DE20015420U1 - Scaffolding covering made of plastic - Google Patents

Description

Plastic scaffolding decking

The invention relates to scaffolding decking which is a component of scaffolding.

The scaffolding decks currently in use can be grouped into three categories: scaffolding decks made of solid wood, scaffolding decks made of all-metal and scaffolding decks made of profiled steel frames with inserted multi-layer wood panels.

Wooden scaffolding decking is known to have the disadvantage that it swells when it comes into contact with water, which has a lasting impact on its static stability. For this reason, such decking only lasts for around 5 years.

The scaffolding decks made of all-metal, preferably galvanized sheet steel or aluminum, which have been introduced for this reason, eliminate this disadvantage, but have the serious problem of being very heavy, even though they are usually designed as gratings. This also means that there is a risk that objects can fall through the gaps in the grating, which could endanger people.

To avoid these problems, proposals have long been made to produce scaffolding flooring from plastic. DE 91 00 667 proposes using materials that accrue from plastic recycling, such as PVC granulate that accrues from the recovery of electrical cables, or plastic mixtures that arise from the shredding of car dashboards. According to the proposal, the scaffolding flooring is provided with reinforcement that is intended to ensure the necessary stability, but also increases the overall weight.

The proposal to produce scaffolding decking from PET material, preferably in the form of granulate obtained from drinks bottles (DE 295 06 072), aims in a similar direction. Several U-shaped, perforated reinforcement profiles parallel to one another are to be incorporated into this material in the longitudinal direction. The decking is also provided with end caps, all-round edge protection and comb-shaped correction holders as internal reinforcement transverse to the longitudinal direction with spacer plates attached in pairs. The edge protection prevents bending by increasing the static stability and also prevents lateral breakage. The reinforcement profiles are made of sheet steel, glass fiber rods or tubes, the edge protection is made of galvanized sheet steel and the correction holders are made of raw steel treated with phosphoric acid.

The solution presented in DE 295 13 421 also aims to reduce weight. To achieve this, the scaffolding consists of a closed casing made of meltable plastic recycling material that has solidified in a mold. Inside, it has a structural design that creates empty or filled cavities, thereby saving weight and plastic material.

The disadvantage of all of these solutions is that, in order to ensure the necessary stability, a large amount of steel reinforcement profiles or reinforcements must be used, which significantly increases the overall weight of such plastic scaffolding. In addition, there are a number of technological problems that stand in the way of cost-effective production.

A plastic scaffolding covering that overcomes these disadvantages is presented in DE 297 11 492.1. Here it is proposed to manufacture the covering from fibre-reinforced plastic. The reinforcing fibres - either artificial fibres such as glass or polyester fibres or natural fibres such as coconut, hemp, sisal

or flax - are embedded in a plastic matrix in such a way that they are in the main load plane and have a load-oriented orientation. The fiber composite is reinforced by needling. The surface of the coverings is non-slip due to thermoplastic deep embossing and milling, which is another significant advantage compared to other developments. Nevertheless, scaffolding coverings made of fiber-reinforced plastic - like all the plastic scaffolding coverings presented - are not yet in use. Since the suitability of the scaffolding coverings is assessed holistically under the aspects of safety (tested), weather resistance, weight, slip resistance and, last but not least, price, the hurdles are correspondingly high.

The aim of the present invention is therefore to overcome the disadvantages of the prior art described above. The aim is to develop a scaffolding covering that is inexpensive to produce and environmentally friendly, with a comparatively low weight and high flexural rigidity, which ensures a long service life and high slip resistance.

According to the invention, this object is achieved in that the scaffolding deck is constructed as a multi-chamber construction consisting of a longitudinal rectangular or trapezoidal chamber segment and upper and lower chords made of fiber-reinforced thermoplastic material which are connected to it in a form-fitting and force-fitting manner.

The profile chambers preferably consist of glass fiber reinforced thermoplastics or of thin sandwich panels made of fiber reinforced plastic, in which the panel core is constructed using thermoplastic fibers with different melting indices in such a way that a network structure is formed which is reinforced by glass fibers. The fiber content in the plastic matrix of the profile chambers or panel cores is at least 50 percent. According to the invention, the profile chambers can also be made of aluminum rectangular or aluminum trapezoidal profiles.

The belts are made of fleece, fabric or scrims combined with glass fibers, aramid fibers or PES fibers and/or mixtures thereof. The thermoplastics used are preferably PP to prevent the adhesion of paint or cement-bound building materials.

The running surface of the covering, i.e. the upper belt, is dimpled with the formation of free-standing fibers to improve slip resistance; according to the invention, rubber granulate can also be vulcanized in for this purpose.

The front sides of the proposed scaffolding deck are designed in such a way that conventional suspension structures can be fitted, which are then connected to the deck in a force- and form-fitting manner.

The present invention thus provides scaffolding coverings that are characterized by a low overall weight, coupled with high load stability and excellent resistance to chemical and biological influences. The material is also easily recyclable.

In the following, the invention is explained in more detail in its basic structure using an embodiment with reference to the accompanying schematic drawing.

Fig. 1 shows the multi-chamber construction with a longitudinal rectangular chamber segment 1, the upper chord 2 and the lower chord 3. In the example, the chords consist of glass fiber reinforced thermoplastic fleece. The raised areas in the form of knobs (not shown in detail) that provide slip resistance are produced by thermoplastic embossing using an embossing stamp, as is already known from DE 297 11 492.1. The raised areas were milled over after embossing, so that tufts of fibers are created that are perpendicular to the longitudinal axis, which

The desired high level of sure-footedness is achieved. Belts 2 and 3 consist of parts that are firmly connected to one another.

Claims (12)

1. Scaffolding decking made of plastic, characterized in that it is constructed as a multi-chamber structure consisting of a longitudinal rectangular or trapezoidal chamber segment ( 1 ) and upper and lower chords ( 2 ; 3 ) connected to these in a form-fitting and force-fitting manner. 2. Scaffolding covering according to claim 1, characterized in that the chamber segment ( 1 ) is a profile chamber made of glass fiber reinforced plastic. 3. Scaffolding covering according to claim 1, characterized in that the chamber segment ( 1 ) is a profile chamber in the form of a thin sandwich panel made of fiber-reinforced plastic, in which the panel core is constructed by thermoplastic fibers with different melt indices so that a network structure is formed which is reinforced by glass fibers. 4. Scaffolding decking according to claim 1, characterized in that the chamber segment ( 1 ) is formed from aluminum profiles. 5. Scaffolding covering according to claims 1 to 4, characterized in that the belts ( 2 ) and ( 3 ) consist of fleeces and/or woven fabrics and/or scaffolds. 6. Scaffold covering according to claims 1 to 5, characterized in that the fleeces, fabrics and scaffolds imply glass fibers. 7. Scaffold covering according to claims 1 to 6, characterized in that the fleeces, fabrics and scaffolds imply aramid fibers. 8. Scaffold covering according to claims 1 to 7, characterized in that the fleeces, woven fabrics and scrims imply PES fibers. 9. Scaffold covering according to claims 1 to 8, characterized in that the fleeces, woven fabrics and scrims imply mixtures of glass and/or aramid and/or PES fibers. 10. Scaffold covering according to claims 1 to 3, characterized in that the fiber content in the plastic matrix of the chamber segment ( 1 ) is at least 50 percent. 11. Scaffolding covering according to claims 1 to 10, characterized in that the upper chord of the covering is dimpled with the formation of free-standing fibers. 12. Scaffolding covering according to claims 1 to 11, characterized in that rubber granulate is vulcanized into the upper chord ( 2 ).