RU2743226C1 - Hydraulic protection system for the underground part of the building - Google Patents

Abstract

FIELD: construction.SUBSTANCE: invention relates to the field of construction, namely to the system of hydraulic protection of the underground part of the building. System of hydraulic protection of the underground part of the building contains a multi-layered structure outside the underground part of the building, including the foundation plate and the underground part of the walls, with an outer waterproof layer, forming a continuous closed loop of waterproofing along the underground part of the building, and with a drainage layer located between the underground part of the building and waterproof layer. The invention contains at least one drainage tray designed to collect and drain water, which is completely located under the foundation plate and the drainage layer and is bounded from below by the specified waterproof layer. The drainage layer is designed to drain water into the specified one drainage tray throughout the specified one drainage tray.EFFECT: technical result is to increase drainage efficiency, simplify hydraulic protection design, simplify and accelerate forming hydraulic protection process.13 cl, 2 dwg

Description

The invention relates to the field of construction, and more specifically to a system for protecting the underground part of a structure from leaks caused by an increase in the level of groundwater, flooding, etc. using drainage.

Currently, in the field of construction in regulatory documents (see, for example, the Code of Rules SP 250.1325800.2016 "Buildings and structures. Protection against groundwater", publ. 08.07.2016) and in practice, several options are used to protect structures from leaks (water protection ) using drainage. They can be conditionally divided into solutions with wall drainage and drainage under the foundation slab. The essence of both solutions is to drain the soil massif, which makes it possible to intercept groundwater at the approaches to the structure. These solutions are quite reliable and are widely used in practice, however, if the underground part of the structure is located in a horizon with high conductivity (where there are large water inflows), they are associated with significant costs and risks, since, even in the case of a short-term interruption of the pumping station , immediately lead to flooding.

In the presence of large water inflows, it is customary to use waterproofing without drainage. However, as a rule, in practice, it is impossible to weld the joints of the waterproofing material without defects over the entire area of the waterproofing, and also not to damage it when filling the sinuses of the pit, therefore, in such situations, various safety means are used. One such means is that dowels with injectors are welded to the waterproofing layer, which divide the area into limited areas. In the event of a waterproofing defect, a repair mortar can be supplied through the injectors. However, the cost of such a solution, and therefore of repair, is quite high.

A more effective approach is to implement a multi-layer waterproofing system with an external waterproofing circuit, inside which a drainage membrane is laid. In the case of local defects in the waterproofing layer, leaks passing through it are diverted along the drainage layer to the base of the structure, where they are collected in an organized manner and discharged into the storm sewer system.

The closest in technical essence to the proposed invention is a system for waterproofing the underground part of the structure, containing a multilayer structure located outside the underground part of the structure, which includes a foundation slab and an underground part of the walls, and the multilayer structure has external and internal layers of waterproofing, forming a continuous closed loop waterproofing along the entire underground part of the structure, and a drainage layer located between the outer and inner layers of waterproofing, and a drainage pit made with the ability to collect water from the drainage layer and drain water into the sewage system (see patent RU 2539456 C2, class E02D 31 / 02, publ. 12/10/2013). The disadvantage of the known solution is the complexity of the design, low drainage capacity and laboriousness of laying the water protection system due to the presence of a large number of layers. In addition, the drainage pit, according to the prototype, is a local, non-extended, object, and water from the drainage layer can enter the drainage pit not along the entire length of the latter, but only in limited areas of the junction of the drainage layer and the drainage pit. These factors can negatively affect drainage efficiency.

The technical problem is the elimination of the indicated drawbacks of the prior art and the development of a more efficient and easy-to-implement water protection system.

The technical result consists in simplifying the design, simplifying and accelerating the process of forming a hydroprotection with an increase in drainage efficiency.

The problem posed is solved, and the technical result is achieved due to the fact that the proposed hydro-protection system of the underground part of the structure, containing a multilayer structure located outside the underground part of the structure, including the foundation slab and the underground part of the walls, with an external waterproofing layer forming a continuous closed loop of waterproofing along the entire underground part of the structure, and with a drainage layer located between the underground part of the structure and the waterproofing layer, contains at least one drainage tray configured to collect and drain water and is completely located under the foundation slab and the drainage layer and bounded from below by the specified waterproofing layer , and the drainage layer is configured to drain water into the specified at least one drainage tray along the entire length of the specified at least one drainage tray.

Preferably, said at least one drainage trough comprises a drainage conduit adapted to drain water from the drainage trough.

Preferably, said at least one drainage tray is filled with a filter bed in which said drainage pipeline is laid.

In a preferred embodiment, the waterproofing system comprises at least one drainage well made inside the waterproofing circuit, and the drainage tray is connected to at least one drainage well with the possibility of collecting water from it or draining water into it, and in at least one drainage well pumping equipment is located.

The drainage layer is preferably continuous along the entire underground part of the structure, except for the junction areas of the drainage layer and at least one drainage well.

The drainage layer is preferably in the form of a profiled drainage membrane.

The waterproofing layer preferably contains a roll-up waterproofing, in particular based on polyvinyl chloride (PVC) or thermoplastic polyolefin (TPO).

The drainage tray in cross section can have the shape of a trapezoid, rectangle, semicircle, semi-oval.

The drainage layer can contact directly with the underground part of the structure, or, alternatively, a protective cement-sand mortar screed can be provided between the bottom surface of the foundation slab and the drainage layer.

Preferably, the multilayer structure also contains an outer protective layer located outside the waterproofing contour and formed by a layer of concrete preparation under the foundation slab and a layer of protective sheet material or a non-removable pit fence along the underground part of the structure wall and along the vertical surface of the foundation slab.

Preferably, the drainage tray is formed by a layer of waterproofing laid on the surface of the drainage trench made in the ground. Alternatively, the drainage channel can be made of concrete with a waterproofing layer on it.

FIG. 1 shows a sectional view of the proposed hydroprotection system, with a cross-section of the drainage tray;

in fig. 2 shows a sectional view of the proposed water protection system, with a longitudinal section of the drainage tray.

The hydroprotection system, generally designated by reference 1, has a multilayer structure located entirely outside the underground part 2 of the structure. As shown in FIG. 1 the underground part of the structure is formed by the foundation slab 3 and the underground part 4 of the walls.

The multilayer structure of the waterproofing system 1 contains an external continuous waterproofing layer 5, which forms an external closed waterproofing loop. The term “closed loop of waterproofing” should be understood as a layer of waterproofing, the joints of which are welded, glued or otherwise hermetically connected and which is not interrupted throughout the entire area of the underground part of the structure.

Preferably, the waterproofing layer 5 is wholly or partially made of a roll-up waterproofing material. For example, polymeric materials such as polyvinyl chloride (PVC) or thermoplastic polyolefin (TPO), which are widely known and used in the art, can be used as such. The advantage of roll-up waterproofing is the ease and speed of installation. However, for all or part of the underground part of the structure, other types of waterproofing can also be used, for example, liquid, injection, coating, etc.

A drainage layer 6 is located between the waterproofing layer 5 and the underground part 2 of the structure. The drainage layer 6 is made of a material with longitudinal water permeability, i.e. is made with the formation of a gap over the entire area of the underground part of the structure, providing free, gravity drainage of water leaks. The material of the drainage layer is able to perceive external pressure without significant deformation, both due to its own strength and due to the strength of the concrete of the walls. Preferably such material is a profiled drainage membrane. In this case, the embossed side of the drainage membrane, i.e. the side forming the specified gap faces the waterproofing layer 5.

The drainage layer can contact directly with the underground part 2 of the structure. Alternatively, as shown in FIG. 1, between the drainage layer 6 and the foundation slab 3, a protective screed from a cement-sand mortar can be made.

The drainage layer 6 is configured to drain water into at least one drainage tray 7 along the entire length of the latter. The drainage channel 7 is completely located under the foundation slab 3 and the drainage layer 6 and is limited from below by the waterproofing layer 5. The drainage channel 7 can be formed by a drainage trench 8, on the bottom and walls of which a waterproofing layer 5 is laid. However, if it is necessary to strengthen the walls and bottom of the drainage trench 8, concrete or other suitable material can be used, on which the waterproofing layer 5 is subsequently laid. The drainage tray in cross-section can have the shape of a trapezoid, rectangle, semicircle, semi-oval, etc.

As shown in the figures, the drain pan may comprise a drain line 9 configured to drain water from the drain pan 7.

The figures also show that the drain pan 7 over the drain line 9 is filled with filter bed 10, for example gravel, crushed stone or other suitable material. Backfill 10 provides a permanent rigid foundation for the drainage layer 6 and at the same time does not prevent the free penetration of water into the drainage line 9.

Preferably, the waterproofing system 1 also comprises an outer protective layer located outside the waterproofing circuit. The outer protective layer under the foundation slab is formed by a layer 12 of concrete preparation, and along the underground part of the wall of the structure and along the vertical surface of the foundation slab - by a layer 11 of protective sheet material. Alternatively, as an external protective layer for the underground part of the wall of the structure and the vertical surface of the foundation slab, a non-removable enclosure of the excavation can be used (for example, "Wall in the ground", Sheet pile, etc.) Protective sheet material for the underground part of the structure wall and the vertical surface of the foundation boards can be ACEID, plywood, brick, wood or other material with appropriate rigidity.

There can also be provided at least one drainage well 13, 14 made (made) inside the waterproofing circuit. The drainage tray 7 can be connected to at least one drainage well 13, 14 with the possibility of collecting water from it or draining water into it. For this, the drainage pipeline 9 is located at a slope towards the drainage well (or one of the drainage wells) with which it is connected. The connection with the possibility of collecting / removing water from the drainage tray 7 and at least one drainage well 13, 14 can be realized by means of a drainage pipeline 9 and / or through holes in the walls of at least one drainage well 13, 14. In at least one drainage well the well 14 may be equipped with pumping equipment 15 for periodically pumping water from the well and discharging it into the sewerage system (not shown in the figures). In particular, pumping down can be performed automatically when a predetermined level is exceeded.

In addition to the function of collecting water, drainage wells 13, 14 are also designed to control the water level, control clogging of the drainage pipeline (s) and system maintenance.

The number of drainage wells (and, accordingly, the drainage trays and pipelines connecting them), in the general case, can be determined by the area occupied by the underground part of the structure, the intensity of water inflows, or other factors. Thus, a plurality of drainage wells can be provided, interconnected by drainage pipes. For example, drainage wells can be evenly spaced across the area of a structure's foundation slab to efficiently collect water. In this case, pumping equipment can be located in at least one drainage well.

In the example shown in FIG. 2, a sectional view of two drainage wells 13, 14 is shown. Drainage pipeline 9 connects drainage wells 13, 14 and is made inclined towards the drainage well 14, in which the pumping equipment 15 is located. The drainage well 13, not equipped with pumping equipment, can be made with the possibility of intermediate collection of water from other drainage pipelines (not shown in the figure).

Alternatively, water can be discharged from the drainage chute 7 or drainage pipeline 9 directly outside the underground part of the structure, for example, into the sewerage system, without the use of drainage wells.

As mentioned above, in practice it is quite difficult to make a continuous waterproofing layer without defects. Due to its distinctive features, the water protection system 1 in accordance with the present invention during operation ensures the drainage of water leaks, which may seep through possible defects of the waterproofing layer 5, into the drainage layer 6 and then into the drainage tray 7, from where, for example, through the drainage pipeline (pipelines) 9 and drainage well (wells) 13, 14, can be discharged from the water protection system 1 into the sewerage system. That is, in addition to the above advantages, the water protection system 1 according to the invention removes only leaks without draining the surrounding massif, in contrast to, for example, wall drainage.

Thus, the hydraulic protection system in accordance with the proposed invention has a simpler design compared to the prototype and allows you to simplify and speed up the installation of the waterproofing system. In addition, due to the absence of the need to repair waterproofing defects, the costs of operating the waterproofing system are reduced. Also, due to the presence of at least one drainage tray, the hydraulic protection system has a greater drainage efficiency due to the larger contact area of the drainage layer and the drainage tray (s), compared to the contact area of the drainage layer and drainage sump in accordance with the prototype.

Claims (17)

1. Hydroprotection system of the underground part of the structure, containing: a multilayer structure located outside the underground part of the structure, which includes the foundation slab and the underground part of the walls, with an outer waterproofing layer forming a continuous closed waterproofing loop along the entire underground part of the structure, and with a drainage layer located between the underground part of the structure and the waterproofing layer, characterized in that contains at least one drainage tray made with the possibility of collecting and draining water and is completely located under the foundation slab and the drainage layer and limited from below by the specified waterproofing layer, wherein the drainage layer is configured to drain water into said at least one drainage tray along the entire length of said at least one drainage tray. 2. The system of claim. 1, wherein said at least one drainage tray comprises a drainage pipeline configured to drain water from the drainage tray. 3. The system according to claim. 2, in which the specified at least one drainage tray is filled with filter bed, in which the specified drainage pipeline is laid. 4. A system according to any of the preceding claims, comprising at least one drainage well made inside the waterproofing circuit, and the drainage tray is connected to at least one drainage well with the possibility of collecting water from it or draining water into it, and at least one drainage well contains pumping equipment. 5. The system of claim. 4, in which the drainage layer is made continuous along the entire underground part of the structure, except for the areas of the drainage layer junction and at least one drainage well. 6. A system according to any one of the preceding claims, wherein the drainage layer is formed as a profiled drainage membrane. 7. A system according to any of the preceding claims, in which the waterproofing layer comprises a roll waterproofing, in particular based on polyvinyl chloride (PVC) or thermoplastic polyolefin (TPO). 8. A system as claimed in any one of the preceding claims, wherein the drain pan has a cross-sectional shape of a trapezoid or rectangle or semicircle or semi-oval. 9. A system according to any of the preceding claims, wherein the drainage layer contacts directly the underground part of the structure. 10. System according to any one of paragraphs. 1-8, in which a protective screed made of cement-sand mortar is made between the lower surface of the foundation slab and the drainage layer. 11. The system according to any of the preceding paragraphs, in which the multilayer structure also contains an outer protective layer located outside the waterproofing circuit and formed by a layer of concrete preparation under the foundation slab and a layer of protective sheet material or a non-removable pit fence along the underground part of the structure wall and along the vertical surface of the foundation slabs. 12. A system according to any of the preceding claims, in which the drainage tray is formed by a layer of waterproofing laid on the surface of the drainage trench made in the ground. 13. System according to any one of paragraphs. 1-11, in which the drain pan is made of concrete.

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