RU2147740C1 - Gear determining water-proofness of concrete - Google Patents

Abstract

FIELD: construction material industry. SUBSTANCE: gear determining water-proofness of concrete is made of pipe-line with taps in which pump, electric contact manometer coupled electrically to pump with the aid of magnetic starter, valve, samples of tested materials with sealing gaskets, electric time counting system that is electrically coupled to surfaces of tested samples via measurement electrodes are arranged. Samples have form of cylindrical sleeves into which metal bushing is pressed, its internal surface has thread used to install samples in ends of taps of pipe-line. Contacts of measurement electrodes which are electrically connected to input of electron system are anchored on surfaces of samples by means of pressing fixtures. To measure water-proofness of samples there is used conductometric method which consists in registration by measurement devices of various abrupt changes of resistance of sections of samples between contacts of electrodes with emergence of moisture in the form of wet spot on outer surfaces of samples which leads to change of voltage supplied from D C source to input of electron system. Reading of time on timer panel stops and sound signal indicating termination of testing process is actuated simultaneously. EFFECT: increased accuracy of determination of moment of appearance of wet spot on outer side of tested sample, simplified design of structure for attachment of samples to taps of pipe-line, reduced time of test. 2 dwg

Description

 The invention relates to the building materials industry, in particular to the field of determining the water resistance of concrete.

 A device for determining the permeability of liquids through hardened concrete (patent 243990, GDR, declared 04.12.85, N 2837027, published 18.03.87, MKI G 01 N 15/08), consisting of a measuring cell mounted on an arm rotating around a vertical axis . A concrete sample is placed in a measuring cell with seals on the surface of the sample. On the one hand, liquid is supplied to the sample through a pipeline; on the other side, an electronic moisture meter is strengthened. When the measuring cell rotates on the bracket, centrifugal forces act on the liquid, under the influence of which it penetrates through the sample. This device provides the speed and sufficient reliability of the research results.

 The disadvantage of this method is the inability to determine the water resistance of concrete above B 8.

 The prototype of the invention is a device for determining the water resistance of concrete according to GOST 127.30.5-84, containing a piping system, a device for deaerating water, a pump, valve devices and manometers, as well as test sockets in which clips with samples of test materials and vessels for collecting the filtrate are installed .

 The disadvantage of the prototype is the low accuracy of determining the degree of water tightness of the studied material, since it is determined visually by the appearance of a wet spot, which does not exclude the subjective measurement error. In addition, the disadvantage can be attributed to the complexity of the fastening and sealing schemes of the samples in the clips and the duration of the waterproofing studies themselves.

 The invention is aimed at improving the accuracy of determining the moment of occurrence of a wet spot on the outside of the test sample, as well as simplifying the design of fastening samples to pipe bends and reducing research time with saving waterproofing materials.

 The solution to the problem is achieved in that in a device for determining the watertightness of concrete containing a pipe with bends, on which samples of the test materials are placed, showing and regulating the water pressure, the samples of the test materials are made in the form of cylindrical glasses with bushings fixed to them with internal threads for installation at the ends of pipe bends; clamping cylindrical cups are connected to the samples, connected by means of a spring with support rings mounted on the surface of the samples; at the bottom of these glasses, springs are laid with contact rings fixed on them, made of electrical insulating material. with the contacts of electrical electrodes placed on them in contact with the lower surface of the sample.

 With the indicated design of the test samples and the method of their attachment to the pipe branches, not only the installation scheme of the test sample is simplified, but also there is no need to seal the surface of the samples themselves, and therefore, the use of sealing materials. At the same time, the time taken to study the samples for water resistance is also reduced. In addition, the design of the pressure cup with measuring electrodes paired with an electronic time reference system makes it possible to more accurately determine the time a wet spot appears on the outer surface of the test sample and thereby eliminate the subjective error of the experiment.

 In FIG. 1 is a functional diagram of the device, which includes a pipe 1 with bends 2, on which a pump 3, an electrical contact pressure gauge 4, electrically connected to the pump 3 via a magnetic starter 5, valve 6, samples of the test materials 7 with gaskets 8, and an electronic system are placed 9 of the countdown, which through the measuring electrodes 10 is electrically connected with the surfaces of the test samples 7. The latter are in the form of cylindrical cups, inside which a metal is pressed the second sleeve 11, having a thread on the inner surface, with which samples 7 are installed at the ends of the bends 2. The clamping devices (figure 2) are attached to the bottom surface of the samples 7, making reliable contact of their surface with the measuring electrodes 10. The clamping device consists of one ring 12, to which a metal cup 14 is suspended by means of flexible springs 13, inside of which there is a contact ring 15 of electrical insulation material with contacts of the electrodes 10. The pressure spring 16 st Akana 14 presses the contacts of the measuring electrodes 10 to the surface of the test sample 7.

 The device operates as follows. First, the test samples 7 are screwed onto the ends of the branches 2 through the gaskets 8, to the surface of which electric measuring electrodes 10 are attached using clamping devices, the ends of which are connected to the input of the electronic device 9. Then the pipe 1 with branches 2 is filled with water using a pump 3, while the valve 6 is open and the incoming air with water is discharged through it out. After filling the inner cavity with water, the valve 6 is closed and the required level of water pressure in it is established by the working pump 3, and it is controlled and supported by an electrocontact pressure gauge 4, which in turn corrects the operation of the pump 3 when the water pressure is changed using the magnetic actuator 5. When the required level is reached water pressures in the internal cavity include an electronic system 10 for counting the time that moisture passes through the walls of the test samples 7. The determination method used is waterproof These samples 7 are known as conductometric and consist in the fact that when moisture appears on the outer surface of samples 7 in the form of a wet spot, the measuring devices 10 record different sharp changes in the resistance of the sections of the samples 7 between the contacts of the electrodes 10, which leads to a change in the applied voltage from the DC power source to the input of the electronic system 9. The time report on the timer display stops and an audible signal is sent at the end of the research process. The time recorded on the timer display using calibration tables determines the quality of the test sample for water resistance.

Claims (1)

 A device for determining the watertightness of concrete, containing a pipe with bends, on which instruments showing and regulating the water pressure are placed, samples of the test materials installed on the pipe bends, characterized in that the samples of the tested materials are made in the form of cylindrical glasses with internally threaded bushings pressed into them for installation at the ends of the pipe bends, clamping cylindrical cups are connected to the samples, connected by means of springs with a support ring, lennym on the sample at the bottom of the cup are stacked with a spring fixed to the contact rings are made of an electrically insulating material, placed on them with electrical contacts of the electrodes in contact with the bottom surface of the test sample.

Images