RU2720344C1 - Method for flow instrumental diagnostics of tightness of dry waterproofing layer of roof - Google Patents

Abstract

FIELD: construction.SUBSTANCE: invention relates to the field of construction control and technical supervision of quality of construction and installation works. Method of flow instrumental diagnostics of tightness of dry waterproofing layer of roof, in which conditional-current-carrying base is provided inside roof so that electroconductive layer is located under diagnosed waterproofing of roof. Then, using the autonomous spark flaw detector, the entire roof surface is inspected, and if a through defect of the waterproofing is detected at the point of its detection, it is fixed with a spark test, occurring between conditionally conductive base and working electrode, on which unlike potentials of high voltage are formed, wherein waterproofing layer protrudes by electric insulator.EFFECT: technical result is higher accuracy of detecting defects in diagnostics of waterproofing layer of roof.3 cl

Description

Technical field

The invention relates to the field of construction control and technical supervision of the quality of construction and installation works, and can be used to diagnose the tightness of waterproofing roofs of complex configuration without pouring roofs with water and soaking insulation.

State of the art

A device is disclosed in the description for Ceja C. Recommended test procedure for high-voltage membrane integrity testing // 28TH RCI International Convention and Trade Show, Chicago. - 2013. The known device allows for instrumental diagnostics of the tightness of waterproofing a flat roof using a high-voltage method. To do this, on one side of the waterproofing, an electrode with a potential from the power source is fed, and an earth wire is connected to the conductive base. In the place of defects in the coating, current flows through the coating and enters the grounded substrate. As a result, a short circuit occurs, that is, an electrical connection of two points of an electric circuit with different potential values. The result of a short circuit is a spark, and thereby damage to the insulation coating is detected.

A known method disclosed in Electronic Leak Detection High vs. Low Voltage // WATERPROOF !. - 2013. The known method involves the detection of leaks in the roof during its diagnosis. unlike voltage potentials are used. In this case, an energy source is used, which contains two terminals providing opposite potentials: one terminal provides a negative potential “-”, which is supplied to the brush electrode, and the other terminal, a positive potential “+”, which is supplied to the base.

A known method of ultra-precise instrumental diagnostics of the tightness of roof waterproofing using the high-voltage method is disclosed in the application for the invention of the Russian Federation 2016148482 (publication date 12/09/2016, IPC G01M 3/16, E04D 13/16). The known method includes fixing the equipment with a short circuit arising between the conductive base and the working electrode, on which the opposite potentials of high voltage are formed, while the waterproofing acts as an electrical insulator. As the equipment for fixing a short circuit, an electrospark flaw detector is used. A high voltage potential with a nominal value of 5 to 41 kV with a working current of 0.0015 A is supplied to the working electrode. Conductive cement-bonded boards, foil-coated heat-insulating materials and fiberglass-based roll materials can be used as conditionally conductive substrates. In this case, if the base of the roof is not represented by a conductive base, then it is modified so that it can conduct current at the stage of construction or reconstruction of the roof.

However, the known solution has insufficient accuracy, since when a voltage of 5 to 41 kV is applied to the working electrode and with a current strength of 0.0015 A, a significant part of the roof defects during diagnostics will not be detected by an electrospark flaw detector. At the same time, in order to ensure the appearance of a spark at the place of detection of the defect, i.e. to achieve circuit closure, consisting of a conductive base, a contact electrode, a flaw detector and a working electrode, it is necessary to use materials that satisfy a number of conditions. So, for example, circuit closure will not occur if the plate material is characterized by a moisture content of less than 7% or rolled materials with a specific electrical resistance (resistivity) of more than 10 ⁵ Ohm * m, even if there is a defect in the waterproofing layer of the roof.

Disclosure of the invention

The technical result achieved by the implementation of the present invention is to improve the accuracy of detection of defects in the diagnosis of the waterproofing layer of the roof.

In accordance with the present invention, a method for streaming instrumental diagnostics of the tightness of a dry waterproofing layer of a roof is provided, in which a conditionally conductive base is provided inside the roof so that the electrically conductive layer is located under the diagnosed waterproofing of the roof, then the entire surface of the roof is checked using an autonomous spark defectoscope, and in case of detection of a through waterproofing defect in the place of its detection, a spark breakdown occurring, m I’m waiting for a conditionally conductive base and a working electrode, on which opposite potentials of high voltage are formed, while the waterproofing layer acts as an electrical insulator, unlike the prototype, plate and monolithic materials with a humidity of more than 7% or heat-insulating and roll are used as a conditionally conductive base materials with a specific electrical resistance of less than 10 ^ 5 Ohm * m, and a high voltage potential with a nominal value of 2 to 50 kV is supplied to the working electrode with a current of nominal value from 0, 15 to 1.0 A, while the roof surface is represented by horizontal, vertical, inclined, complex curved surfaces or their combinations.

The implementation of the invention

Under the conditionally conductive base for the purposes of the present invention means a base of any material, modified so as to be used as a conductive layer.

Providing conditionally conductive base inside the roof, in particular, can be carried out during the construction or reconstruction of the roof. Preferably, plate and monolithic materials with a moisture content of more than 7% or heat-insulating and roll materials with a specific electric resistance (resistivity) of less than 10 ⁵ Ohm * m are introduced into the composition of the roof. In particular, slab and monolithic material can be represented by a cement-bonded particleboard, characterized by a moisture content of more than 7%. In particular, the heat-insulating and roll material can be represented by a composite material based on fiberglass or fiberglass. When using similar materials characterized by other values of humidity or electrical resistivity, the principle used in the present invention will not work: there will be no circuit closure at the place of detection of the defect.

The complex configuration of the roof involves various combinations of vertical, horizontal, inclined surfaces, both essentially flat sections of the roof, and protruding elements, joints of roofing materials, spill funnels, parapets. A suitable version of the conductive base is selected based on the configuration of the roof. In the joints of the roofing sheets or on the vertical surfaces of the structures protruding above the roof, contact electrodes are installed in order to then connect an autonomous spark detector to them, while ensuring reliable electrical contact between the conductive base and each contact electrode.

Preferably, the ground cable of said flaw detector is connected to a contact electrode mounted on an electrically conductive base. In particular, if it is impossible to connect directly to this base, the flaw detector is grounded by a capacitive method. When checking the surface of the roof, the operator uses a working electrode, in particular a brush electrode, to which a high voltage potential with a nominal value of 2 to 50 kV is preferably applied at a current strength of 0.15 to 1.0 A. If the current and voltage values beyond these intervals, during the diagnosis, either a significant part of the waterproofing defects will be skipped, or the waterproofing surface will be damaged. Stream diagnostics involves checking the area of the entire roof surface, each square centimeter of it.

In case of detection of a through waterproofing defect in the place of its detection, a spark breakdown is fixed that occurs between the conductive base and the working electrode, on which opposite potentials of high voltage are formed, while the waterproofing layer acts as an electrical insulator. Upon detection of a defect, the spark flaw detector gives an audible and / or light alarm.

The present invention can also find its application in both civil and industrial construction, while the objects of diagnostics can be external and internal waterproofing of buried reinforced concrete structures (including foundations and small metro stations), fire tanks, parking lots, industrial technical tanks etc.

Claims (6)

1. A method for streaming instrumental diagnostics of the tightness of a dry waterproofing layer of a roof, in which: - provide conditionally conductive base inside the roof so that the electrically conductive layer is located under the diagnosed waterproofing of the roof, - then, using a spark defectoscope, the entire surface of the roof is checked and, if a through waterproofing defect is detected in the place of its detection, a spark breakdown occurs between the conditionally conductive base and the working electrode, on which the opposite potentials of high voltage are formed, while the waterproofing layer acts as an electrical insulator , - characterized in that as a conditionally conductive base, plate and monolithic materials with a humidity of more than 7% or heat-insulating and roll materials with a specific electric resistance of less than 10 ⁵ Ohm * m are used, and a high voltage potential with a nominal value of 2 to 50 is applied to the working electrode kV at a current of nominal value from 0.15 to 1.0 A, while the roof surface is represented by horizontal, vertical, inclined, complex curved surfaces or their combinations. 2. The method according to claim 1, in which the conductive base is provided inside the roof during its construction or reconstruction. 3. The method according to claim 1, in which the spark flaw detector is an autonomous spark flaw detector.