SU1339442A1 - Device for checking quality of building materials - Google Patents

Abstract

The invention relates to non-destructive testing and can be used to control the quality of artificial building conglomerates (suit) with extra-strong properties. The aim of the invention is to expand the functionality by increasing the information content of the control. According to the invention, in the device for controlling the quality of construction materials, the exciter exciter 2 mounted at one end of the acoustic waveguide 1 is made in the form of an impeller. The piezoelectric elements 3 are rigidly fixed on the blades of the impeller. The point of attachment of the acoustic waveguide 1 is located in its center of mass. Having determined the acoustic resistance of the CLAIM with the longitudinal oscillations of the waveguide 1, its compressive (tensile) strength is evaluated, and with the transverse oscillations, the shear strength. The comparison of the obtained resistance values with the selected strength criteria determines the quality of the CLAIM. 2 Il. - AL. 05 with so 4 4 ;: Yu

Description

 //, //// F.

By tugging the waveguide 1 in the ev center of mass with the help of clamping screws 7 of the sleeve 6, fixed on 5, conditions are created for the propagation of transverse oscillations with the least attenuation. Consequently, the action of longitudinal and transverse waves is strictly differentiated. In addition, for the separation of these waves, a special reception of 4 oscillations is used, which converts mechanical oscillations into a non-temporary electrical voltage,

The receiver 4 is made in the form of a piez electric bimorph rectangular carbon plate, fixed in type

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The invention relates to the field of non-destructive testing and can be used to control the quality of artificial building conglomerates (lawsuit) with a viscoelastic 1-n and properties, HanpiiMep asphalt concrete 5 pavements and laboratory samples.

The aim of the invention is to expand the functionality by increasing the information content of the control.

FIG. I shows a diagram of a device for controlling the quality of building materials; FIG. 2 is a section A-A in FIG. one.

The device contains an acoustic waveguide 1, on the upper end of which the oscillator 2 oscillator is fixedly mounted, made in the form of a krish-20 sapphire needle, having a point

bending console "At the free end of the console is fixed

The caps, piezoelectric elements 3 are fixed on the blades of the impeller, while the blades' planes are parallel to the axis of its rotation. At the other end of waveguide 1, a 4-oscillation receiver is installed with the possibility of displacement 1P1H along waveguide 1 and having a point contact with it,

In order to prevent the waveguide I from tipping over, 1 when installing it, a metal frame 5 is used. With the aid of a fastening mechanism consisting of a sleeve 6 rigidly attached to the metal frame 5 and clamping screws 7, the waveguide 1 is attached at its center of mass. In this case, the receiver 4 oscillations attached to the metatElehichesky frame 5 and is connected with a dial indicator 8, for example, a millivoltmeter. GTezoelements 3 are connected to the generator 9 connected to the frequency meter 10 “Waveguide 1 is installed on the test material 1 1”

The device works as follows. ,

By means of the generator 9, a harmonic voltage is applied to the piezoelectric element 3, the exciter 2 oscillations and free from the material under study.

11 waveguide 1 excite sinusoidal longitudinal and transverse

(torsional) vibrations. By changing the frequency of the oscillator 9, the resonance of standing waves in waveguide 1 is achieved.

contact with the waveguide 1. Receiver 4 is sensitive only to displacements that are directed perpendicular to the plane of the piezoelectric bimorph

25 Plasma Einas. If the receiver 4 oscillations is set so that the plane of the piezo-plates is perpendicular to the axis of waveguide 1, then it is sensitive only to longitudinal oscillations. If the plane

30 of the piezoplates are parallel to the waveguide axis G, then the receiver 4 is sensitive only to transverse vibrations.

The receiver 4 oscillations are set in a certain position depending on what acoustic resistance is measured: during compression (stretching) or shear of the material under study 1. If necessary, two receivers are installed that are sensitive to different types of waves, and information is obtained from them alternately.

The amplitude of oscillation of the waveguide 1 is determined using a switch.

45 of the indicator 8, to which the signals of the receiver 4 oscillations. At the moment of resonance, the deviation of the indicator hand 8 reaches its maximum. According to the readings of the frequency meter 10, the resonant frequency f,.

Waveguide I is introduced into contact with the material under study 1I and, by changing the frequency of the generator 9, produces- Since the propagation speeds progg re tune the system in longitudinal and transverse waves into the matter resonance of standing waves. In this case, the waveguide can have a frequency of the device and choose two resonances in the main tones, depending on the desired depth of the material that is explored from each other in frequency. Register

394422

By tugging the waveguide 1 in the evo center of mass with the help of clamping screws 7 of the sleeve 6, fixed on 5, conditions are created for the propagation of transverse oscillations with the least attenuation. Consequently, the action of longitudinal and transverse waves is strictly differentiated. In addition, for the separation of the action of these waves, a special 4-oscillation receiver is used, which converts mechanical oscillations into a temporary electric voltage,

The receiver 4 is made in the form of a piezoelectric bimorph rectangular plate, fixed in type

ten

.

l-20 sapphire needle, having a point

 sapphire needle, having a point

bending console "At the free end of the console is fixed

contact with the waveguide 1. Receiver 4 is sensitive only to displacements that are directed perpendicular to the plane of the piezoelectric bimorph

Place Eina. If the receiver 4 oscillations is set so that the plane of the piezo-plates is perpendicular to the axis of waveguide 1, then it is sensitive only to longitudinal oscillations. If the plane

piezoplates are parallel to the waveguide axis G, then the receiver 4 is sensitive only to transverse vibrations.

The receiver 4 oscillations are set in a certain position depending on what acoustic resistance is measured: during compression (stretching) or shear of the material under study 1. If necessary, two receivers are installed that are sensitive to different types of waves, and receive information from them alternately.

The amplitude of oscillation of the waveguide 1 is determined using a switch.

indicator 8, which receives signals from the receiver 4 oscillations. At the moment of resonance, the deviation of the indicator hand 8 reaches its maximum. According to the readings of the frequency meter 10, the resonant frequency f,.

resonant frequency t with repeated resonance.

The total acoustic resistance of the material under study 11, both under tension (compression) and shear, is calculated by the expression

 Z.

(2n-1) f, 2

Where

 and

- input acoustic impedance of the material;

-wave waveguide resistance;

-resonant frequency of the waveguide without contact with the material under study ;:

-resonant frequency of the waveguide in contact with the material;

-the width of the resonance curve in contact with the material;

- harmonic number.

In one measurement cycle, one value of the acoustic resistance of the CLAIM is determined for compression (tension) or shear. In order to obtain an integrated material characteristic, two measurements were made. Having determined the acoustic resistance of the CLAIM with longitudinal vibrations, its compressive strength (stretching) is evaluated, and with transverse oscillations, the strength at

af

P

39442

shift. The higher the value of acoustic impedance, the greater the strength of the material. Comparing the obtained resistance values with selected strength criteria characterize the quality of the CLAIM.

Thus, the use of a device for controlling the quality of construction materials provides for obtaining a comprehensive quality characteristic under longitudinal and transverse loads in a dynamic mode, which expands its functionality. .

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Claims (1)

Invention Formula A device for controlling the quality of building materials, containing an acoustic waveguide, at one end of which an oscillator with piezoelements is fixedly mounted, an oscillation receiver with the possibility of moving along the acoustic waveguide and a waveguide attachment mechanism, characterized in that , the exciter is made in the form of an impeller, piezoelements are rigidly fixed on the blades of the impeller, and the attachment point is acoustic-waveguide laid in its center of mass. 35 Compiled by I. Ardashev Editor I. Shulla Tehred M. Khodanich Proofreader M. Demchik Order 4213/13 Circulation 776 Subscription VNIIPI USSR State Committee Inventions and discoveries 113035, Moscow, Zh-35, Raushsk-nab. 4/5 Proizv1; | .g gnenno-polygraphic enterprise, Uzhgorod, st. Project, 4 2