SU842497A1 - Device for determination of building structure air-tightness - Google Patents

Description

At the same time, water from the protection tank is consumed for horizontal filtration, and at the boundaries of the central container, backwater is created from the protection tank to ensure filtering of the drain from the central container only in the vertical direction. Thus, the flow rate from the central tank, measured by the flow tube, is due only to directional filtration, the coefficient of which is therefore calculated using the Darcy formula of the same name. The use of a protective container furthermore allows one to eliminate the influence of defects in the lateral sealing of the chamber, leading to leakage from under the protective container of water, if the latter’s reserve in it lasts for the entire test period and the pressure in the containers is kept constant. SZ, The disadvantage of this device is the impossibility of excluding or taking into account the effect of possible defects of the internal seal (seal around the perimeter of the supply tank). If there is a gap between the edge of the supply tank and the surface of the concrete caused by an uneven or rough surface, the water from this tank leaks according to the law, telling the vessels to the security chamber, as the water level in it decreases faster. Due to the fact that this flow of water can neither be noticed nor eliminated, when testing a structure with an uneven or rough surface or at the joint between the concrete slabs, the ambiguity of the obtained results may occur. The purpose of the invention is to improve the accuracy of determining waterproof coatings. This goal is achieved by the fact that a device for determining the waterproofness of building structures, containing a flow chamber with a primary tube, annular auxiliary chamber and pressure distributor, is equipped with a surge tank, the auxiliary chamber is equipped with a water meter tube, This surge tank is connected to the pressure distributor and to the water tube of the auxiliary chamber. The drawing shows a diagram of the proposed device. 7 The device contains a central flow chamber 1 (the main measuring part of the device) connected through a water meter tube 2 to a pressure distributor 3 having an air pump inlet 4. To create an annular auxiliary chamber 5 at the boundaries of the flow chamber, the flow and security chambers are attached to the construction of self-wedging anchors 6 through sealing gaskets 7 around the perimeters of the tanks. The security tank also has a water meter tube 8 connected by means of a hose 9 to a distributor 3 of a head. A leveling tank is located above the water meter tube 8 - a tank 10 connected to it from the bottom through the metering valve I1, and on top of that the hose 9 is connected to the pressure distributor 3. The pressure distributor has a hole with a plug 12, and a surge tank 10 with a plug 13. The device works as follows. The device is assembled and fixed to the surface of the concrete structure using a self-wedged anchor with „„ „„ „„ „„ „moat, the number of which is calculated ,,. .- - FROM the strength of concrete, the test pressure and the open area of the chamber. Pre-tank 10 is filled with water through the opening 13 (valve I1 is closed). Into the chambers, through the distributor 3, water is poured into the hole 12 to the top, sealed and using an air pump to create the necessary test pressure (up to 2 atm) in the water tubes 2 and 8 and the surge tank 10. When the water level reaches the main (central) water tube, the metering valve of the surge tank and the same water level are set in the additional water meter tube (later regulating the opening of the metering valve, the equality of the water columns in the main and additional water meter tubes.) This establishes complete equality of the water pressures in the supply and additional chambers and the absence of horizontal current at the boundary between them, even if there are gaps under the seal. During the tests, the duration of which is equal to the passage time of the level of the measuring tube, Pressure: The filtration coefficient is calculated from the known volume of the tube, the area of the supply tank and the resulting test time. The proposed construction of the chamber makes it possible to guarantee the reliability of filtration tests of structures with a surface characterized by a roughness of up to 3 mm (under a meter rail), as well as when ng standing in the test zone of a movement joint up to 4 mm deep. At the same time, the presence of residual gaps under the outer and inner sealing does not affect the test result, but only increases the flow of water from the security chamber. This is especially important when testing concrete clothes of channels and dams, the requirements for the flatness of which are not high.

The increase in the reliability of the watertightness test increases the reliability of the design, which allows in some cases to refuse laboratory tests of concrete for water permeability with sampling.

school,

1961, p. 237-240.

M.

Higher

Claims (2)

3. Full-scale tests of channel impervious clothes for waterproofing. - Inter-information of the Central Scientific Research Institute of the Ministry of Water Resources of the USSR No. 21-78, ser. 21-14, 197B (prototype. 7 Claim I: A device for determining the water tightness of building structures, comprising a flow chamber with a water tube, an annular auxiliary chamber and a pressure distributor, characterized in that, for the purpose of increasing the accuracy of determination, the device is equipped equalizing capacity, auxiliary, the chamber is equipped with a water meter tube, wherein the equalizing capacitance is connected to the pressure distributor and to the water meter tube in the help chamber. Niemann for the examination 1.Patent US number 3,861,146, Cl. 73-38, published. 1975. 2. Vadyunina A.F. Methods for studying the physical properties of soils and soil.