SU900187A1 - Device for investigating solidifying material physical mechanical properties - Google Patents

Description

The invention relates to physicomechanical research, in particular to the study of hardening materials of structures operating in conditions of difficult stress, changing thermal conditions and high humidity.

A device for studying the physico-mechanical properties of hardening materials is known, comprising a nozzle with holes fixed to the sensor and contact elements made of needles and placed with the possibility of longitudinal movement in the nozzle holes [1].

However, in the case of installing the sensor in the test medium of hardening material, a nozzle fixed to the housing prevents the acoustic contact of the elastic sound-conducting gasket with the environment. In this case, insignificant acoustic contact is realized only through needle contact elements2. Given the large attenuation in an elastic sound-conducting pad, the power of the emitted signal will be very small. In addition, jamming of needles due to the ingress of particles of the test material into the nozzle openings can lead to slipping of the needle contact elements and loss of acoustic contact with the medium, for example, under the combined action of thermal and mechanical loads.

The closest in technical essence is a device for studying the physicomechanical properties of hardening materials, comprising a housing with an acoustic transducer mounted in it on a rigid plate and connected to a coaxial cable [2].

The disadvantages of the known device are the possibility of jamming of the moving part of the sensor, for example, due to falling into the gap between the guide clip and the membrane part of the investigated material of its components or as a result of mechanical and thermal effects. In addition, with the difficult-stressed state of the material under study and the simultaneous effect of temperature, there is a possibility of loss of acoustic contact between the working surface of the sensor and the material under study due to the different nature of deformations in different directions. In addition, this sensor is not tight and can emit signals not only from the working surface, but also through the housing.

The purpose of the invention is to increase the reliability and accuracy of the study in conditions of difficult stress at elevated temperatures and moisture; nosti.

This goal is achieved in that the device for studying the physicomechanical properties of hardening materials, comprising a housing with an acoustic transducer installed in it on a rigid plate connected to a coaxial cable, is equipped with a flexible plate connected to the housing and a rigid plate, as well as the converter is a fixture, the housing being coated with sound-absorbing material, and the rigid plate is equipped with anchors. s

Furthermore, biasing acoustic transducer device is designed as a contact with each other contact plate cylinders _t-symmetric gasket shaped washers and nuts, and the coaxial cable is secured within the housing by a nut, wedge clamping washers. gaskets.

While the free ends of the anchors ⁴ are located in different planes.

Moreover, the acoustic transducer is connected to the rigid and contact plates with conductive glue.

In FIG. 1 shows a device ^g for studying the physicomechanical characteristics of hardening materials, section; in FIG. 2 is a view A in FIG. 1.

An acoustic transducer 1, for example made of TsGS-.19 piezoelectric ceramics, is mounted on a rigid metal plate 2 to which different anchors 3 are fixed on the opposite side, the free ends of which are located in different planes ·, the shape of the anchors can be different. The most appropriate T-shape with different lengths of anchors on the periphery and center.

The rigid plate 2 is attached to the housing 4 of the device through a flexible plate 5, for example, by contact welding. The pressing acoustic transducer 1 device, made in the form of a contact plate 6 in contact with each other, a cylindrical plate 7, a shaped nut 8 and a washer 9, and the shaped washer 9 abuts against the gasket 10.

To fix the coaxial cable 11, the device has a wedge clamp made in the form of a cylinder 12 with a conical recess and a cut housing 13 and installed between the nut 14 and the washer 15.To seal the cable passage, a sealing ring 16 of elastic material is installed in a special opening of the nut 8. To seal the device, all free cavities from the side of the nut 14 and to the nut 8 during assembly can be made with a sealant or polymerizable compound.

To eliminate the “acoustic connection of the device through.” The side surface of the housing, when it is mounted in the product, it is provided externally with a sound-absorbing coating 17 made of an elastic material that simultaneously provides freedom of movement of the device along the longitudinal axis under conditions of joint action of mechanical and temperature loads, which helps to ensure constant and reliable acoustic contact due to anchors 3 independent of the magnitude of the longitudinal and transverse deformations.

In the case of operation of the device in conditions of increasing temperatures, all elastic elements and sealing compounds are made of heat-resistant materials.

The device operates as follows.

After assembly, the device is installed in the form or formwork of the structure before it is filled with the test material, for example, before concreting.

The ultrasonic signal of the acoustic transducer 1 through a rigid plate 2 enters the test material regardless of what phase it is in ·. ' liquid or solid.

After solidification of the test material, the acoustic transducer 1 through a rigid plate 2 with anchors 3 is mechanically connected to the environment, which ensures reliable acoustic contact between the test material and the acoustic transducer 1.

In the future, the movement of the test material due to deformation occurs together with the rigid plate 7 and the acoustic transducer 1. Therefore, the working part of the device has constant and unchanged contact with the test material and does not lose contact with it until the destruction of the test material.

Coaxial cable 11 is crimped by a wedge clamp and gasket 16, which ensures reliable sealing of the device. The presence in the device of sound-absorbing material 17 ″ with which the housing 4 is covered provides freedom of movement of the device along the longitudinal axis under conditions of combined exposure to mechanical and thermal loads.

The operating temperature range is practically limited only by the permissible operating temperatures of the acoustic transducer and coaxial cable, which can be quite high.

Claims (2)

39 between the guide case and the membrane part of the studied material of its components or as a result of mechanical and thermal effects. In addition, if the material under test is difficult and the temperature is simultaneously exposed, there is a possibility of acoustic contact between the sensor's working surface and the material under investigation due to the different nature of deformations in different directions. In addition, this sensor is not sealed. and can emit signals not only of the working surface, but also through the housing. The purpose of the invention is to increase the reliability and accuracy of research under conditions of a complex stress state at elevated temperatures and humidity. The goal is achieved by the fact that the device for studying the physicomechanical properties of hardening materials, comprising a housing with an acoustic transducer mounted thereon on a rigid plate, connected to a coaxial cable, sleeps with a flexible plate connected to the housing and a rigid plate, as well as pressing an acoustic transducer. the expander is a device, the casing is covered with sound-absorbing material, and the rigid plate is provided with anchors. In addition, the clamping acoustic transducer device is made in the form of contacting with each other contact plate, cylindrical gasket, figured washers and nuts, and the coaxial cable is fixed in the case with a nut, wedge clamp, washer and. pads. In this case, the free ends of the anchors are located in different planar. Moreover, the acoustic transducer is connected to the rigid and contact plates by conductive glue. In FIG. 1 shows a device for studying the physicomechanical characteristics of hardening materials, a section; in fig. 2 is a view A of FIG. 1. Acoustic transducer 1, for example, from PZT-.19 piezoceramics, is mounted on a rigid metal plate 2, to which different anchors 3 are fixed on the opposite side, the free ends of which are located in different planes, the shape of the anchors can be different. The most appropriate T-shaped form with different lengths of anchors on the periphery and center. The rigid plate 2 is attached to the device body k via a flexible plate 5i, for example, by resistance welding. The clamping acoustic transducer 1 is a device made in the form of a contact plate 6 in contact with each other, a cylindrical plate 7, a figured nut 8 and a washer 9, and the figure washer 9 abuts against the gasket 10. In order to fix the coaxial cable 11, there is a wedge in the device, made a cylinder 12 with a conical recess and a cut body 13 and installed between a nut and a washer 15. To seal the cable passage, a sealing ring 1b made of an elastic mother is installed in a special outlet nut 8 ala In order to seal the device, all free cavities on the side of the nut 14 and up to the nut 8 during assembly can be made with a sealant or a polymerizing compound. To eliminate acoustic communication of the device through the lateral surface of the housing when mounted in the product, it is provided on the outside with a sound-absorbing coating 17. made of an elastic material that simultaneously ensures the freedom of movement of the device along the longitudinal axis under the conditions of combined mechanical and thermal loads, which contributes to ensuring constant and reliable acoustic contact through anchors 3 independent of the magnitude of the longitudinal and transverse strains. In the case of operation of the device under conditions of increasing temperatures, all elastic elements and sealing compositions are made of heat-resistant materials. The device works as follows. After assembly, the device is installed in a form or formwork of a structure before it is filled with an object under study, for example, before concrete material development. The ultrasonic signal of the acoustic transducer 1 through the rigid plate 2 enters the material under investigation, regardless of what phase it is in; liquid or solid. After solidification of the material under study, the acoustic transducer 1 is mechanically connected with the environment through the rigid plate 2 with the anchors 3, which ensures reliable acoustic contact between the material under test and the acoustic transducer 1. Subsequently, the displaced material is displaced with the rigid plate 7 and acoustic Converter 1. Consequently, the working part of the device has constant and constant contact with the material under study and does not lose communication with it until fracture uc Followed material. The coaxial cable 11 is crimped with a wedge clamp and a gasket 16, which ensures reliable sealing of the device. The presence of a coping material 17 in the device, which is covered by the housing 4, ensures the freedom of movement of the device along the longitudinal axis under the conditions of the combined effect of mechanical and temperature loads. The operating temperature range is practically limited only by the permissible operating temperatures of the acoustic transducer and coaxial bel, which can be quite high. Claim 1. A device for the study of physical and mechanical properties harden 7. comprising a housing with an acoustic transducer mounted thereon on a rigid plate connected to a coaxial cable, characterized in that, in order to increase the reliability and accuracy of the study under complex stress conditions at elevated temperatures and humidity, the device is equipped with a flexible plate, an acoustic transducer with a device connected to the housing and a rigid plate, as well as a clamp, the housing is covered with a sound-absorbing material, and the rigid plate is equipped with nkerami. 2. The device according to claim 1, wherein the clamping acoustic transducer device is made in the form of a contact plate, a cylindrical gasket, a figure washer and a nut in contact with each other, and the coaxial cable is fixed in the housing with a nut, a wedge clamp, washers and gaskets. 3. The device according to paragraphs. 1 and 2, it is known that the free ends of the anchors are located in different planes. k. The device according to claims 1, 2 and 3, is characterized in that the acoustic transducer is connected to the rigid and contact plates by conductive glue. Sources of information taken into account in the examination 1. The author's certificate of the USSR N 602853, cl. G 01 N 29/0, 1975. 2. Authors certificate of the USSR 260271, cl. G 01 N 33/38, 1968. . / 7 "13 15 16 / S 9 -, t ywijywwYwy-Mtyyxxyv / L S (; lCHCH Di-. | -. XvSSJj s to..(, t / a. / . 2