RU2441121C1 - Monolithic roof-protective coating of operational purpose - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: in a monolithic roof - a protective coating of operational purpose made as multilayer and consisting of a slope-forming screed 2, laid on a base 1 of a power floor slab, a priming layer 3, filled with quartz sand 4 during application, which serves function of a steam insulation layer, a hydraulic insulation layer 5 is made as a hydraulic insulation membrane by pouring polymer materials of higher elasticity, for instance, methyl methacrylate, types of matacryl, polyurethane and other polymers that withstand tension (elongation) in case of rupture of at least 200%. The bearing high-strength layer 6 is made of a polymer binder of similar origin, but with lower deformation characteristics and is filled with quartz sand by at least 100% of the binder's mass. In the finishing top layer 7, made as polymer, thickness, colour, chemical resistance, extent of roughness and other characteristics are determined by conditions of operations of a specific roof. At the same time all polymer layer are made in a seamless monolithic version.

EFFECT: increased operational reliability of the roof.

6 cl, 4 dwg

Description

The invention relates to the field of construction, namely, the arrangement of a roof or protective coatings of various structures for the purpose of operation, for example, parking lots, sports facilities, residential buildings, leisure centers, trade and exhibition halls, etc.

The modern choice of heat-insulating, waterproofing and finishing materials allows the roof to be exploited practically without any serious technical barriers and to include these materials in projects when designing new cottages and estates. Such exploitable roof solutions save the plot area and are also an attractive architectural design element.

The installation of an exploited roof is a complex engineering task, requiring in its decision to comply with a number of requirements for modern high-tech roofing.

Known roof for a building with a flat roof, made of a multilayer, consisting of a waterproofing layer located on the surface of the base of the roof, a heat insulating layer of tightly laid rubber crumb, a layer of polymeric material, a porous layer, which is a hardened binder made of a polymeric material with it filler in the form of rubber crumb, all layers, except for heat and sound insulating and waterproofing layers, are laid by the method of filling technology with the possibility of providing them in aimosvyazi interconnected by a polymeric material and the formation of the monolithic structure of the roof covering (RF №58577 patent publ. 27.11.2006 g).

The disadvantages of the analogue are associated with a high degree of deformability of the structure, in which elastic polymer materials filled with rubber crumb are used. For any heat and sound insulating layer, a necessary condition for ensuring the thermophysical characteristics is the invariance of its geometric shapes, since any changes (deformations) of them affect the density of the heat insulating layer and its porosity, and, consequently, the thermal conductivity characteristics in the direction of deterioration. In addition, the roofing technology used in the analogue creates a heterogeneity of the structure in the heat-insulating layer, since after pouring the polymer material over this layer, in its upper part, the entire porous space is filled with polymer material, and thus it becomes divided into two parts: the lower - porous and upper with filled pores of the material of the bulk layer. In this case, the porous (upper finishing) layer is also filled with rubber crumb and polymer material, only initially mixed with it in the bulk layer. Such a heterogeneous structure, but connected into a monolith during sharp daily temperature fluctuations in the winter period, for example, in St. Petersburg, where the normal daily differences are from -10 to + 10 ° С, increases the likelihood of a dew point inside the structure, with all the ensuing negative consequences.

The low resistance of elastic polymer structures to pricking and cutting loads requires the creation of a protective layer, for example, of gravel or crushed stone dust, which is unacceptable for a heat insulator layer. In addition, any other loads on the roof (pedestrian traffic, mechanical loads, including transport, snow) due to its deformability can change geometric parameters, including given slopes, which will lead to the formation of water accumulation places randomly located on the roof ( puddles), which in winter turn into ice. For these reasons, the operation of such a roof is impossible.

A traditional flat exploited roof is known, consisting of a vapor barrier layer, a hard insulation, a slope forming layer and a screed, a waterproofing layer consisting of, for example, a weldable roll material or a polymer roll membrane, bonded together by welds, a protective layer that includes a geotextile a layer for protection against spillage of gravel with sharp edges, for example, granite gravel is used as drainage, and an upper layer consisting, for example, of paving slabs (C NIP II-26-76. Roofs. Appendix II, type P-9, p.14).

The disadvantages of the prototype is that although such a roof protects the waterproofing layer from falling of heavy and sharp objects, it improves the fire protection properties due to the protective layer of granite gravel and paving slabs, however, this type of roof is not intended for use as an exploited roof with appropriate loads and functional purposes, for example, parking, traffic and parking of vehicles and cleaning equipment, recreation areas and terraces, ramps and overpasses, galleries, cafes, sports grounds.

An inverse roof is known, consisting of a concrete slab with a slope arranged on it, on top of which there is a reinforced screed of cement-sand mixture primed with bitumen TECHNONICOL primer No. 1, a roofing carpet made of two layers of waterproofing material, the lower one from Technoelastost B or Technoelast- Fix, the upper one from Tekhnoelastmost B or Tekhnoelast-Green, which is covered with a layer of needle-punched geotextile TekhnoNikol, a layer of insulation located on top of the waterproofing layers and perform their function of protecting the building from moisture, a drainage layer for removing moisture arranged on the upper surface of the insulation boards, with insulation laid on it, on which a granite drainage layer is applied, on top of which a reinforced screed is laid, before laying which the previous surface is covered with glassine or roofing material forming a separation layer, on which the top layer is applied - asphalt concrete (Guide to the design and installation of operated roofs using bitumen-poly ernyh materials company "TekhnoNIKOL", Moscow, 2005, section 3, subsection 3.1. Inversion operated structure used for moving or parking vehicles).

By the greatest number of similar features and achieved by using the result, this technical solution is selected as a prototype of the claimed invention.

The disadvantages of the prototype are congestion due to the bias (under the waterproofing layer) and the protective (above the thermal insulation layer or in the absence of it above the waterproofing layer) screeds, as well as the upper operating layer leads to high loads on the base plate, for the removal of which it is necessary to carry out additional expensive measures to increase the bearing capacity of the base. In case of violation of the continuity of the waterproofing layer (leaks) and, if necessary, repair work is required, for example, disassembling the upper layer of the inverse roof, reuse of which, like screeds above the insulating layer, is impossible, as a result of which a new screed is required, which is an expensive operation. Due to the multi-layered construction of the roof, which involves draining water from several of its intermediate layers, even with small deformations of one of them, the risk of leaks increases due to movements in transition zones (joints) and along multi-level drainage funnels, which requires frequent repairs with partial disassembling the roof in places of drainage.

The technical result, to which the claimed invention is directed, consists in increasing the efficiency and expanding the types of exploitation of the roof, optimizing and reducing the cost of its structure and increasing the reliability during operation.

To achieve the specified technical result in a monolithic roof - a protective coating for operational use made of a multi-layer and consisting of a slope-forming screed, laid on the base of the power floor slab, a primer layer, when coated with quartz sand, acting as a vapor barrier, the waterproofing layer is made in the form of a bulk waterproofing membrane from polymeric materials of increased elasticity, for example methyl methacrylate, types of matacryl, polyurethane and other poly measures that can withstand tensile (elongation) at break of at least 200%, the bearing high-strength layer is made of a polymer binder of a similar origin, but with less deformation characteristics and is filled with quartz sand at least 100% by weight of the binder, and in the top-layer, made by polymer, thickness, color, chemical resistance, roughness and other characteristics are determined by the operating conditions of a particular roof - a protective coating, while all polymer layers are made on slope forming b ton screed in seamless monolithic implementation.

In addition, the claimed decision has optional features characterizing its particular cases, namely:

- to protect the slope-forming concrete screed from cracking and ensure the strength of the base for polymer layers, it is made of concrete with a strength of at least M250 (B20), a thickness of at least 40-50 mm in its lower part, and a thickness of at least 0.75t over the entire area where t is the thickness of the slope-forming concrete screed, with cards with a step L of not more than 6 × 6 m, compensation temperature-shrink joints are filled with polymer material of a monolithic roof-protective coating;

- the expansion joint of the bias-forming concrete screed is made of a waterproofing key installed in the lower part of the seam, over which the entire space is filled with elastic polymer material, so that the waterproofing membrane and the deformation layer work together without an intermediate primer layer, laid only on the concrete base of the bias-forming concrete screed and vertical surfaces of expansion joints and joints of the screed to the walls (parapets);

- in the adjacencies, the waterproofing membrane is walled onto the walls (parapets), while thixotropic additives are included in the composition of the polymer material, and the highly-loaded layer of polymer material is made in the form of a plinth with a height h of at least 10-15 cm, the space between the inclined concrete screed and the parapet filled with elastic polymer material;

- to relieve stress concentrations on the polymer layer, the sharp angles of the slope-forming concrete screed in the expansion joints and joints are cut at an angle of 45 °;

- when using a monolithic roof - a protective coating in temperate climatic zones or with insignificant temperature differences that do not cause significant temperature deformations in the screed, a waterproofing membrane can be applied only in places of possible structural movements of the load-bearing elements of the building, adjoining to the walls of parapets or expansion joints, and The bearing high-strength layer of the roof is applied directly to the primer layer.

Distinctive features of the proposed device from the above, closest to it, are the implementation of the waterproofing layer in the form of a waterproofing membrane in bulk from polymer materials of increased elasticity, withstanding tensile (elongation) at break of at least 200%, the implementation of the bearing high-strength layer of a polymer binder of similar origin, but with less deformation characteristics, filled with quartz sand not less than 100% by weight of the binder, top-finish loya polymer and the performance of all polymer layers in a seamless monolithic design.

Due to the presence of these features in the proposed monolithic roof - a protective coating for operational use, the coating is monolithic and seamless, since the use of a material of the same origin, but with different characteristics (brands) makes it possible to meet the requirements for operating roofs with a small thickness of the roof. At the same time, the multilayer structure works as a single monolithic structure with different characteristics and functional purpose of the layers, but high adhesive and mechanical interlayer strength, water resistance, for example, vapor barrier - primer layer, waterproofing - elastic layer, bearing - high-strength layer, top - protective and finishing top -layer. The implementation of layers of polymeric materials makes it possible to regulate (improve, if necessary, existing grades) various characteristics of the layers by introducing special additives in the composition of polymers, for example, thixotropic additives - for application on vertical surfaces, flame retardants - to increase fire resistance classes, etc.

Filling compensation temperature-shrinkage (and expansion joints and joints to the walls (parapets) with an elastic polymer composition of the waterproofing membrane improves the performance of the slope-forming concrete screed creating a protective damping layer, which unloads this screed from the extreme temperature-shrinkage deformation, which prevents its destruction, and increases the reliability, and increases its reliability and increases waterproofing membrane while ensuring the continuity of the waterproof layer, since the main volume of deformation the load is “extinguished” at the seams, creating a “safety margin” for the main waterproofing layer of the proposed roof.

All layers of a monolithic roof - a protective coating are completely waterproof both individually and in a monolith. Accordingly, the collection and removal of water into the drainage funnels is carried out only from the surface of the proposed roof and does not require multi-tiered.

The multilayer nature of such a roof allows you to redistribute the load between the layers, creating a kind of “safety margin”, which, when one layer is destroyed, does not entail simultaneous destruction of the subsequent one. In the present invention, due to the created tight adhesive bonds between the layers of the polymer coating, the options for the penetration of water under the polymer layer are excluded. Possible destruction, for example, violation of the integrity of the waterproofing membrane will be limited only to the local area, which is easily determined visually and does not require disassembly of the entire roofing carpet.

The use of colored quartz sand in a bearing high-strength layer gives decorativeness to this roof. And if necessary, you can create drawings by combining various colors of sand. Drawings (sections of various colors) are performed by separate cards according to the templates and do not violate the continuity (waterproofness) of the bearing high-strength layer. Another option for a design solution may be laying film with photo drawings on a carrier layer and coating it with a transparent finishing layer. In addition, the finishing layer itself can be colored (pigmented).

The minimum thickness of the waterproofing membrane, and therefore the loads transferred to the base, creates significant reserves for the installation of additional exploitable structures, such as sports fields, fountains, mini-pools, flowerbeds, helipads, without reinforcing the existing load-bearing structural elements of the building.

A high degree of resistance to thermal deformations and a small thickness of the roof allows for the installation of heating systems on the slope-forming concrete screed, without impairing the characteristics of the roof carpet, ensuring the absence of frozen and snowy areas during the period of negative temperatures.

The proposed monolithic roof - a protective coating for operational purposes is illustrated by the drawings presented in figures 1-5.

Figure 1 shows a section of a monolithic roof - a protective coating.

Figure 2 - cutting compensation temperature-shrink joints.

Figure 3 is a section of the connection node of a monolithic roof-protective coating with a deformation seam.

Figure 4 - section of the junction of the monolithic roof-protective coating to the walls (parapets).

A monolithic roofing-protective coating for operational purposes consists of a base of a roof 1, for example, a power floor slab, a slope-forming concrete screed 2, a vapor barrier layer of primer polymer 3, quartz sand 4, a waterproofing membrane made by pouring from an elastic polymer material 5, bearing a high-strength layer 6 of polymer a binder of a similar origin with lower deformation characteristics and filled with quartz sand 4, a top-coating layer 7, and compensation temperatures o-shrink joints 8 filled with polymer material 9, expansion joints of the screed 10 and base plate 11, abutment 14 of the upper part of the concrete screed 2 to the walls (parapets) 12, baseboard 13, waterproofing keys 15.

Monolithic roofing - a protective coating for operational purposes works as follows (figure 3).

On the basis of the proposed roof - a protective coating consisting of a power slab 1 of the floor, a slope-forming concrete screed 2 is laid with concrete strength of at least M250 (B20) and a thickness in its lower part of the spillway funnels of at least 40-50 mm. The expansion joints 10 slope-forming concrete screed 2 are combined with the expansion joints of the power plate 1 overlap. In places of the device expansion joints 10 and abutments 14 slope-forming concrete screed 2 to the wall (parapet) 12 (figure 4), a removable formwork is installed. Next (Fig. 2) after laying the concrete in a slope-forming concrete screed, 2 cards with a step L of no more than 6 × 6 m are cut over the entire area to a depth of at least 0.75 t, expansion temperature-shrink joints 8 and are filled with polymer material 9. Acute slope-forming corners concrete screed 2 in the upper part of the expansion joints 10 and abutments to the walls (parapets) 12 are cut off at an angle of 45 ° (Figs. 3, 4). After preparing the base of the roof 1, removing the removable formwork, grinding and dusting off the slope-forming concrete screed 2, a primer layer 3 is made of a polymer material, for example methyl methacrylate, which has not only the characteristics required for the operation of a monolithic waterproofing roof, but also technological advantages compared with other polymeric materials ( fast, within 1-2 hours, strength gain); to increase the adhesion of the primer with the overlying layers, quartz sand is sprinkled evenly on its surface 4. Along with applying a vapor barrier layer from the primer polymer 3, compensating temperature-shrinkable joints 8 are filled with polymer material 8. At the bottom of the expansion joints 10 and junctions 14 are in slope-forming concrete coupler 2 is installed waterproofing keys 15.

A primer layer (polymer) 3 thus prepared, with a thickness of at least 1.5-3.0 mm, is applied to the screed by pouring a waterproofing layer in the form of a waterproofing membrane made of flexible polymer material 5 with high deformation characteristics, for example, Nanten DC 225 acrylic compositions or Nanten Matacryl Modified Urethane Coated with high adhesion to acrylics.

Before applying the waterproofing membrane layer, these compositions fill the expansion joints 10 and abutment 14 of the inner part of the slope-forming concrete screed 2 to the walls (parapets) 12, and at the junctions of the upper part of this screed 2 to the walls (parapets) 12, the waterproofing membrane smoothly with a slight increase in thickness corner part is wound up on the walls (parapets) 12. This allows the expansion joints 10 to withstand various loads during operation (compression, bending and tensile deformation, etc.), i.e. perform the functions inherent to the structural bearing, while protecting the slope-forming concrete screed 2 and acting as a stress compensator from the occurrence of ultimate stresses that can cause its destruction.

Similarly, compensation heat-shrink joints 8, which are performed to relieve stresses in concrete and prevent it from operating in the mode of ultimate (destructive) deformation loads, being filled with a polymer composition, actually glue the sections cut into cards, on the one hand, create additional strength reserves for the action of ultimate loads, and on the other hand, create a monolithic base on a slope-forming concrete screed 2, on which the load from the external (vertical) loads is evenly distributed, connected concerned with the operation of the proposed roof. Thus, filling with polymer materials deformation 10 and compensation temperature-shrink 8 joints in this roof involves the creation of rigid adhesive bonds between the polymer and concrete in the joints, giving a new quality to the slope-forming concrete screed 2, which works as a monolithic concrete slab (structure) made of concrete and polymer, which allows you to evenly redistribute all the arising loads (stresses) on it, significantly increasing the reliability in operation of this roof base.

Further, a high-strength bearing layer 6 made of a polymer binder, for example, Nanten DC 205 acrylic varnish, having a lower tensile (elongation) tensile, but greater compressive strength filled with 4 quartz sand mass is not applied to a waterproofing membrane with a thickness of at least 2-6 mm less than 100% by weight of the binder. At the junctions 14 of the slope-forming concrete screed 2 to the walls (parapets) 12, the bearing high-strength layer 6 is made in the form of a plinth 13 with a height of h 10-15 cm.

In climatic zones where temperature fluctuations during the day are large, for example, in St. Petersburg, it is advisable to mix Nanten 225 and Nanten 205 in a ratio of 50:50, which will significantly increase the deformation characteristics of the bearing high-strength layer 6 without changing its compressive strength. And the size of the quartz sand fraction 4 is selected depending on the thickness of the bearing high-strength layer 6 and is not more than 1/3 of its thickness. The use of colored quartz sand expands the possibilities of decorative design of the proposed monolithic roof - a protective coating, without compromising its characteristics and is selected based on the selected architectural solutions on this roof - a protective coating.

On top of the supporting high-strength layer 6, by painting or pouring, depending on the thickness of the layer, an acrylic topcoat 7 is applied, for example, Nanten 305 varnish, which must be high-strength and resistant to ultraviolet radiation. The coating thickness, color, and when colored quartz sand is filled with a high-strength carrier layer, is colorless, the degree of roughness, and other decorative-geometric parameters of the top-7 finishing layer are selected based on the actual operating conditions of the proposed roof-protective coating.

Hard adhesive bonds between the layers completely exclude the penetration of water into the interlayer space. In case of violation of the continuity of the waterproofing membrane 5 in the proposed roof - protective coating, the destruction can be local in nature and can be easily detected, and repairs are carried out within a few hours without disassembling most layers.

Therefore, the creation of a single monolithic, rigidly bonded, multilayer homogeneous polymer structure, on the one hand, allows you to redistribute the loads transferred to it, and on the other hand, due to the individual properties of each layer together with other roof elements (deformation 10 and compensation temperature-shrink 8 with sutures, junctions 14) take on the ultimate load for a particular section of the load: in the lower layer — tensile deformations, in the upper part — compressive stresses. In the event of failure or destruction of one layer, this does not entail the simultaneous destruction of others, since stress unloading occurs only in the destroyed layer, and the rest remain completely waterproof. Those. the multilayer roof actually creates several levels of structural protection and localizes possible violations of the waterproofing continuity. And the presence of a waterproofing key 15 prevents the entry of water from the roof into the underlying premises of the building, in case of destruction of the entire multilayer structure.

The lack of technological operations associated with the use of fire (for example, the obligatory use of a torch for surfacing roll materials on traditional roofs), significantly increases the fire safety of the proposed roof - a protective coating both during its installation and during repair.

Thus, the proposed roof - a protective coating for operational use can improve the reliability of the roof - the coating during its operation and its economy due to the multilayer coating, giving a new quality slope-forming concrete screed, as the main bearing element of the roof, which is in a tight adhesive bond with a polymer coating, to exclude water resistance to localize violations of the integrity of the waterproofing as a whole, to create additional reserves of the strength of the base of the roof.

Claims (6)

1. Monolithic roofing - a protective coating for operational use, made of multi-layer and consisting of a slope-forming screed, laid on the base of the power floor slab, a primer layer, when applied covered with quartz sand, performing the function of a vapor barrier, characterized in that the waterproofing layer is made in the form of a waterproofing membrane in bulk from polymeric materials of increased elasticity, for example methyl methacrylate, types of matacryl, polyurethane and other polymers that withstand tensile (elongation) at a break of at least 200%, the bearing high-strength layer is made of a polymer binder of a similar origin, but with less deformation characteristics and is filled with quartz sand at least 100% by weight of the binder, and in the top-finishing layer made of polymer, the thickness, color, chemical resistance, degree of roughness and other characteristics are determined by the operating conditions of a particular roof - a protective coating, while all polymer layers are made on a slope-forming concrete screed in a seamless monolithic om performance. 2. Monolithic roofing - a protective coating according to claim 1, characterized in that to protect the slope-forming concrete screed from cracking and to ensure the strength of the base under the polymer layers, it is made of concrete with a strength of at least M250 (B20) and a thickness in its lower part of at least 40 -50 mm, and over the entire area with a thickness of not less than 0.75t, where t is the thickness of the slope-forming concrete screed, while cards with a step L of not more than 6 × 6 m are cut compensation shrink joints filled with a polymer material of a monolithic roof - a protective coating . 3. Monolithic roofing - a protective coating according to claim 1, characterized in that the expansion joint of the bias-forming concrete screed is made of a waterproofing key installed in the lower part of the joint, over which the entire space is filled with an elastic polymer material, so that the waterproofing membrane and the deformation layer worked together without an intermediate primer layer, laid only on the concrete base of the slope-forming concrete screed and vertical surfaces of expansion joints and joints screeds to the walls (parapets). 4. Monolithic roofing - a protective coating according to claim 1, characterized in that in adjoining the waterproofing membrane is wound on the walls (parapets), while thixotropic additives are included in the composition of the polymer material, and the bearing high-strength layer of polymer material is made in the form of a plinth with a height h not less than 10-15 cm, the space between the slope-forming concrete screed and the parapet is filled with elastic polymer material. 5. Monolithic roofing - a protective coating according to claim 1, characterized in that to remove stress concentrations on the polymer layer, the sharp angles of the slope-forming concrete screed in the expansion joints and joints are cut at an angle of 45 °. 6. Monolithic roofing - a protective coating according to claim 1, characterized in that when using a monolithic roofing - a protective coating in moderate climatic zones or with insignificant temperature differences that do not cause significant temperature deformations in the screed, a waterproofing membrane can be applied only in places of possible structural movements of the building's load-bearing elements, abutments to the walls of parapets or expansion joints, and the load-bearing high-strength layer of a monolithic roof - a protective coating is applied directly on the primer.

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