RU214708U1 - Polymer cellular slab for the formation of concrete structures - Google Patents

Abstract

The utility model relates to the construction and repair of buildings, the formation of temporary road structures, suspended slabs, floor slabs, as well as plastic slabs intended for the formation of concrete surfaces in monolithic construction. A polymer cellular slab for the formation of concrete structures is a longitudinal cellular structure, the layers of which are made of polyethylene, while the cells are isolated from each other. At the same time, the ends along the perimeter of the plate are closed, and the polyethylene from which the plate is made is made on a twin-screw extruder. The achieved technical result consists in increasing the mechanical strength of the plate during production and use, which is achieved by creating a closed cellular structure around the entire perimeter of the plate during manufacture. Also, an increase in mechanical strength is achieved through the use of a twin-screw extruder, the number of heating-cooling cycles is reduced, and polymer degradation is reduced.

Description

The utility model relates to the construction and repair of buildings, the formation of temporary road structures, suspended slabs, floor slabs, as well as plastic slabs intended for the formation of concrete surfaces in monolithic construction.

From the utility model patent of the Russian Federation No. 168326, a formwork panel made of expanded polyvinyl chloride - PVC is known, which is a single structure with a variable density in width from the center of the panel to at least one of its outer surfaces in such a way that the density is at least one its outer surface is higher than the density in the center of the panel. The panel consists of: PVC 50-55 wt.%; wood flour 10-15 wt.%; calcium carbonate (CaCO ₃ ) - 20-30 wt.%; chemical additives up to 10 wt.%.

The disadvantages of such panels are high cost, low environmental friendliness, labor-intensive chemical foaming process, and it is technologically difficult to obtain a uniform structure in the production of such panels.

Known formwork form with stiffeners from the utility model patent of the Russian Federation No. 64242, which is mounted before pouring concrete and is used to hold concrete and dry concrete, and which is mounted and maintained in the mounted state for a certain period of time after drying concrete, made of flexible polyvinyl chloride - PVC, and having walls between the upper and lower levels, which will ensure uniform load distribution over them.

Such panels have a number of disadvantages, namely: high cost and complexity in manufacturing; there is no possibility of restoring damage resulting from use; uneven distribution of the load on one sheet, where there are walls and in places where there are air cavities, use only in slab formwork and the inability to use for the production of wall formwork.

The closest analogue is the Chinese patent CN209339596U - https://patentimages.storage.googleapis.com/3f/30/ea/9cfb30378228de/CN209339596U.pdf

This panel is made using a single-screw extruder, according to the technology of which, for the production of a finished product, the use of pre-made granules on additional equipment (compounder) is required, where secondary polypropylene is used as a polymer matrix, which is mixed with modifiers, plasticizers, fillers, etc., forms mixture, after which it is heated and granules are made from it. Further, from prefabricated granules (compound), a polymer plate is produced on a line with a single-screw extruder made of recycled polypropylene. In the manufacture of panels by this method, the quality of the panel itself (declared physical and mechanical properties) deteriorates, due to the fact that the heating-cooling that has passed through several polymer processing cycles, the number of bonds between polypropylene molecules decreases in proportion to the increase in the number of recycling cycles and causes destruction (fragmentation ) macromolecules, i.e. degradation of the polymer.

The product formula of the Chinese panel is designed mainly for operation in southern latitudes, for example, in Asia and the Middle East, where the temperature during monolithic work can reach plus 55 degrees Celsius.

The ends of this panel are open, due to the presence of holes along the entire length of the panel, during concreting, concrete milk containing water flows, which expands at low temperatures and destroys the integral structure of the sheet.

The objective of this utility model is to create polymer plates for the formation of concrete structures that do not have the above disadvantages.

Solving the problem, the technical result is achieved, which consists in increasing the mechanical strength of the plate during production and use, which is achieved by creating a closed cellular structure around the entire perimeter of the plate during manufacture.

Bearing capacity refers to the ability of a polymer board to withstand the ultimate load while maintaining normal operation. An increase in the ultimate load of the structure leads to plastic deformation of the plates.

For the manufacture of the claimed polymer plates, the use of previously manufactured compound granules is not required, as in the closest patent, since all components for the manufacture of plates (polyethylene, modifiers, plasticizers, etc.) are fed directly to the production line through special high-precision feeders into a twin screw extruder. The result is a material - polyethylene, processed on a twin-screw extruder (using a saving technology) with a decrease in the destruction of the material, which improves the quality of the product - its mechanical strength.

Also, the preservation of mechanical strength from excessive destruction of the material during heating-cooling is achieved through the use of a twin-screw extruder.

As the main polymer matrix for the production of our polymer boards, polyethylene is used, mainly low pressure HDPE (HDPE) in combination with metallocene low pressure polyethylene (mLLDPE) . The use of polyethylene as the main base allows you to significantly expand the use of plates at sub-zero temperatures, without special frost-resistant additives, and the chemical formula of the product, developed specifically for polymer plates based on polyethylene, allows you to maintain physical and mechanical parameters at the level of the carrier matrix made of polypropylene, which is used in Chinese patents.

The implementation of such a model for the production of polymer plates makes it possible to reduce the complexity of manufacturing a multilayer structure of a plate, where a combination of secondary polymer is located inside, and a primary and additionally sufficient economic effect is achieved from the outside, as a result of which it becomes advisable to use both primary polyethylene granules and a combination of primary and secondary polyethylene for production, as well as to produce single-layer boards, which further simplifies the production process and makes boards at a lower cost.

The plate has closed ends around the entire perimeter from the ingress of the external environment. The external environment is understood as objects, materials that do not belong to the slab, but which can affect it, in particular - water, snow, concrete, etc.

The closure of the ends - honeycomb cavities, is achieved in a semi-automatic mode of operation, namely, by rolling the plate through hot steel rollers, as a result of which, during the rolling of the plate, the ends of the plate are heated from the side of the holes, which are closed (sealed) with a molten polymer from its own plate or another in a way that allows you to achieve the result when the ends of the plate are closed from the ingress of water (or other objects) into the product. If water, concrete mix or other materials get inside the slab, it will negatively affect the mechanical strength of the slab, especially when it is used in high and low temperature conditions.

The use of a saving technology for closing the ends of the product makes it possible to increase the number of cycles of using plates by at least 25% when using a combination of primary and secondary polymer with additives compared to the Chinese panel. In the case of the use of only primary polymer with modifying additives, made using a saving technology in one layer, it allows to increase the service life of polymer plates by at least 50%, the number of cycles of using the plate in the formation of monolithic structures.

The specified technical result is achieved in a polymer plate for the formation of concrete walls and ceilings, which, according to the utility model, is a longitudinal cellular structure, the layers of which are made of polyethylene, while the cells are isolated from each other.

The use of polyethylene as the main polymer matrix makes it possible to create polymer plates that do not lose their characteristics at low and high temperatures, which makes it possible to perform monolithic work at temperatures from minus 40 degrees to plus 45 degrees Celsius. At the same time, polymer plates can be used repeatedly, with the possibility of restoring damaged sections of the plates with a special polymer material.

In one embodiment, the board comprises outer layers made from a combination of virgin and recycled high impact polyethylene, with an interior made from a combination of virgin and recycled polymer with additives to impart flexibility to the board. In this case, each cell in the cross section is a circle or a square.

The utility model is illustrated by drawings, where in Fig. 1 shows a general view of the formwork slab with a circular section of the cells; in fig. 2 - general view of the formwork panel with a square section of the cells; fig. 3 - photograph of a panel with a circular section of the cells; fig. 4 is a photograph of a panel with a square section of cells, FIG. 5 - photograph of a plate with closed round cells made in one layer of polyethylene with additives.

A closed-type polymer cellular slab for the formation of concrete structures is a longitudinal cellular (honeycomb) structure (Fig. 1, 2), three layers of which are made of a recycled polymer with modifiers, while the cells inside the slab are isolated from each other and are located along the entire length plates.

In the manufacture of polymer boards, a combination of primary and secondary polyethylene with various additives is preferably used, which can be up to 60% by weight, which may include additives to increase rigidity, wood flour, talc, chalk and other modifiers and plasticizers that give polymer boards the required physical and mechanical properties.

Working surface - the outer layers of the slab (if the slab is made in three layers), which are in direct contact with concrete, have a thickness of 2 to 3 millimeters and consist of a reinforced formula based on HDPE low pressure polyethylene in combination with additives according to the product formula, density about 1000-1200 kg / m3 and is formed by a special slotted head during the manufacture of the product.

Polyethylene as a material is characterized by high moisture resistance. Plates made of this material do not absorb water, remain elastic in the cold, do not break, do not increase in size due to the intake of water, are highly resistant to acids and alkalis, do not rot and are not subject to corrosion, i.e. keep their dimensions constant during operation. Thus, the use of polyethylene makes it possible to maintain the bearing capacity due to mechanical strength, and also makes it possible to manufacture slabs with a closed-type cellular structure, which makes it possible to protect the slab from destruction at low temperatures, as a result of concrete milk entering the slab through open ends during concreting.

In the manufacture of polymer plates, the technology of creating a longitudinal cellular structure along the entire length of the product was applied (Fig. 3). The use of a cellular structure made of polyethylene ensures uniform distribution of the load over the entire polymer plate and high mechanical strength of the plate. Each cell is divided by a partition. Each partition acts as an additional stiffener, which leads to an increase in the bearing capacity of the slab. The load on the polyethylene polymer slab, as a result of exposure to the concrete mixture, is distributed evenly over the entire outer surface and internal structure of the slab, which ensures a constant quality of the concrete surface around the entire perimeter of the concrete pour.

An additional result in the manufacture of the proposed boards is a reduction in the cost of the product when using a saving technology.

The cells of the polymer board, forming a honeycomb structure, can have a round inner base (see Fig. 1 or a square section of Fig. 2), the cellular structure of the products at the same time allows you to reduce the weight of the plate and increase their load-bearing characteristics.

The type of polymer boards with a circular cell section better forms bends when forming complex monolithic structures and better holds nails and screws during formwork installation, and also slightly reduces the cost of the product due to the use of a simplified board manufacturing process, with the possibility of producing polymer boards in one layer and are used mainly for slab formwork.

If it is necessary to increase the service life of the polymer board, which is especially important for the formwork of walls that experience heavy loads in the manufacture of monolithic structures, they are produced with square cells and reinforced outer layers 3 (Fig. 2), consisting of a combination of primary and secondary polyethylene of increased rigidity with modified additives that give additional wear resistance to the formwork board and increase the water-repellent properties.

The production of all layers of the polymer board takes place during one production cycle and eliminates the delamination of the outer layers.

The plate manufacturing method is injection molding, extrusion. The boards are produced on a special production line, which includes: a twin screw extruder, a forming head, a calibration device, a cooling unit for finished products, receiving table, equipment for automatic laying of slabs, as well as equipment used for cutting slabs into standard sizes of 1220×2440 mm and 1500×3000 mm with a thickness of 15 to 21 mm and other product formats, according to the terms of reference.

As an example of the implementation of a polymer plate with a square section of cells, a plate can be considered, each cell of which in the cross section is a square of 4×4 mm. The number of cells per 1 cm ² is 9 pieces. The thickness of the plate is from 12 to 21 mm. When resizing, the number of cells per 1 cm ² does not change.

For plates with a circular cross section, the cell diameter can be 3.0-4.5 mm. The thickness of the plates in this case also ranges from 12 to 21 mm.

During the production process, the slab is homogeneous and monolithic around the entire perimeter of the structure. Due to the rolling rollers, which in the course of their work refine the outer layers of the polymer plate in order to reduce adhesion to concrete, the layers are smooth and no lubricants are required during operation, which saves in construction and installation work.

The proposed design of polymer plates for formwork of walls and ceilings of a cellular structure, in addition to increased mechanical strength, is additionally characterized by reduced cost, ease of operation, lighter weight, ease of use of nails and screws compared to analogues, the ability to be applied in the construction industry.

Repurchase of slabs from manufacturers of monolithic works makes it possible to reduce the cost of the product and additionally ensures environmental protection.

Specifications of polymer board Shore D hardness ≤58 Impact strength with Charpy notch, kJ/m2 ≤14 Bending strength, MPa ≤30 Bending modulus, MPa ≤2800 Water supply % ≤0.5

Claims (5)

1. Polymer cellular slab for the formation of concrete structures, which is a longitudinal cellular structure, while the cells are isolated from each other, characterized in that the longitudinal cellular structure is made of polyethylene processed on a twin-screw extruder, and the ends of the plate along the perimeter are closed. 2. Polymer cellular slab for the formation of concrete structures according to claim 1, characterized in that it is made of a combination of primary and secondary polyethylene with additives. 3. Polymer cellular slab for the formation of concrete structures according to claim 1, characterized in that it has reinforced outer layers made of primary polyethylene with increased wear resistance with additives. 4. Polymer cellular slab for the formation of concrete structures according to claim 1, characterized in that each cell in the cross section is a square. 5. Polymer cellular slab for the formation of concrete structures according to claim 1, characterized in that each cell has a circular cross section.

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