RU2763987C1 - Device for infrared thermography of polymer composite materials in a constant magnetic field environment - Google Patents

Abstract

FIELD: measuring technology.

SUBSTANCE: invention relates to the field of measuring technology, namely to devices for performing non-destructive testing of products made of polymer composite materials (PCM). A device for infrared thermography of polymer composite materials in a magnetic field environment is claimed, which contains a frame for fixing the control object on which a tripod with a video camera is placed. At the same time, the frame is equipped with guides with bars with electromagnets installed in them with the possibility of movement. The video camera is mounted by means of a swivel joint on a horizontal tripod rod at a distance from the object of control, providing an optimal focal length for recording a thermal diagnostic signal from the object of control.

EFFECT: possibility of recognizing the undercured state of the matrix PCM.

1 cl, 1 dwg

Description

The invention relates to the field of measuring technology, namely to devices for non-destructive testing of products made of polymer composite materials (PCM).

One of the most dangerous defects in products made from PCM is the undercuring of the binder (matrix), which is characterized by a degree of polymerization of less than 95-98%. The presence of this defect leads to a sharp decrease in the operational properties and the nature of the destruction of PCM parts under static and dynamic loading.

According to GOST R 56787-2015 “Polymer composites. Non-destructive testing” to determine the undercured state of the PCM matrix, it is possible to use only one single method - ultrasonic flaw detection. Ultrasonic flaw detection, despite being widely used in various industries when used in relation to polymer composite materials, has some disadvantages, which include: high attenuation of acoustic waves, the likelihood of retaining and absorbing a liquid acting as a conductive medium, as well as the need for a relatively even and smooth surface to perform control. Another effective non-destructive ultrasonic flaw detection method is infrared thermography, which allows you to quickly examine large surfaces, identifying areas that need to be subjected to more thorough inspection.

When recognizing the undercured state of the polymer matrix of a composite material by infrared thermography, the amorphous (disordered) structure of the polymer, the presence of microregions with an increased local order, with higher intermolecular bonds complicates the determination of the temperature boundary of the solid and undercured states.

A known method of infrared thermography of the uncured state of the PCM matrix under the influence of a constant magnetic field (PMF) on the control object. This method consists in the fact that in solid polymers, under the action of PMF, the mechanical characteristics change and orientational phenomena are observed in the polymer medium. Thus, due to the appearance in controlled areas with a complete and undercured state of the PCM matrix under the action of PMF and orientational phenomena of zones with different degrees of molecular order, it becomes possible to determine the temperature boundary between them when performing infrared thermography (see Kosenko E.A., Zorin V. .A,, Baurova N.I. Analysis of the influence of a constant magnetic field on the results of quality control of parts made of polymer composite materials by infrared thermography / All materials. Encyclopedic reference book. 2018. No. 7. P. 30-33).

A wide range of equipment for performing infrared thermography is known, from simple (hand-held thermal imager (infrared video camera) and heat gun) to complex (completely integrated systems with computer control). This equipment allows you to register the temperature distribution over the entire surface of the test object during or immediately after heating (or cooling) the controlled area. A change in the intensity of the heat flux caused by defects located close to the surface affects the resulting temperature distribution on the surface of the test object. Heating of the control object is carried out due to the implementation of the mechanisms of heat conduction, convection and radiation. Typical defects detected by this equipment include voids, fillings, cracks, delaminations and the presence of liquid media (see GOST R 56787-2015 "Polymer composites. Non-destructive testing").

A disadvantage of the known equipment is the impossibility of recognizing the uncured state of the PCM matrix.

The closest analogues to the claimed technical solution from the field of technology have not been identified.

The technical result achieved by using the proposed invention is to provide the possibility of recognizing the uncured state of the PCM matrix.

The technical result is achieved by the fact that the device for infrared thermography of polymer composite materials in a magnetic field contains a frame for mounting the test object, two electromagnets and a tripod with an infrared video camera. In this case, the electromagnets are located on the slats opposite each other on both sides of the frame with the possibility of moving along the frame, as well as towards each other and in the opposite direction. The infrared video camera is mounted on a horizontal stand at a distance from the test object, which provides the optimal focal length for recording a thermal diagnostic signal from the test object. The lens of the infrared camera is directed to the frame, strictly perpendicular to the test object.

The presence in the installation of two electromagnets located opposite each other makes it possible to create constant magnetic fields in the frame area, the lines of force of which have the same direction and are parallel to each other.

The possibility of moving the electromagnets towards each other and back allows placing test objects of various overall dimensions on the frame between them. In this case, the intersection of the lines of force created by electromagnets of magnetic fields should be ensured.

Electromagnets are removable and, if necessary, can be replaced by electromagnets with other quantitative characteristics of the magnetic field.

Infra-red lamps, flash lamps, spotlights can be used as a heating source of the control object, convection heating with warm air is possible, if necessary, the control object can be cooled for measurements.

The proposed device, when performing infrared thermography, makes it possible to create orientational phenomena in the structure of the polymer matrix of the composite, leading to a different degree of ordering of molecules in zones with a fully cured and undercured matrix, making it possible to identify the temperature boundary between them and the temperature diagnostic signal characterizing the presence of a defect.

The proposed device is illustrated by drawings, where in Fig. one schematically shows the general view of the device.

The device for infrared thermography of polymer composite materials in a magnetic field contains a frame 1 on which the test object 2 is placed. move along them. A transverse rod 7 with a holder 8, in which an infrared video camera 9 is hinged, is moved along the tripod stand in a vertical direction with the possibility of rotation around an axis in a horizontal plane, while its lens is directed to the frame. Linear bearings are installed in the fastening 10 of the transverse rod to the rack, ensuring its smooth linear movement.

The proposed device operates as follows.

On the frame 1 in the environment of a constant magnetic field between two electromagnets 6 is placed the object of control 2 of the polymer composite material. The object of control can be preheated, or subjected to heating by any of the known methods (except for heating in a liquid medium) in the process of performing infrared thermography. By moving the transverse rod in the vertical direction, the optimal focal length between the infrared video camera 9, hinged in the holder 8, and the object of control is set. If the focal length does not allow covering the entire control area, then by moving the transverse rod 7 in the longitudinal direction by means of the fastener 10 and/or turning it around the tripod post 3 in the horizontal plane, a step-by-step recording of changes in the distribution of the temperature field on the surface of the object is performed using an infrared video camera. control. The synchronous movement of the bars 5 along the guides 4 and the electromagnets along the bars allows you to create a constant magnetic field in different areas of a large-sized test object.

The present invention is illustrated by examples.

Example 1

An example of the implementation of the device is the implementation of infrared thermography for the presence of an undercured connecting blade of a gas turbine compressor (object of control) made of basalt plastic, the components of which are a biaxial basalt fabric with a 0/90° fiber reinforcement direction and epoxy resin. The blade is placed on the frame of the device. In the area where the blade is located, with the help of two electromagnets located on both sides of the test object, a constant magnetic field with a strength of 68 A/cm is created. Adjustment of the location of the electromagnets relative to the object of control is carried out by moving them along the guides and along the slats. Under the influence of a constant magnetic field, orientational phenomena are created in a solid polymer, which make it possible to determine the temperature boundary between zones with different degrees of molecular order. The control object is subjected to slow heating using infrared lamps. Registration of the temperature diagnostic signal from the control object is carried out using an infrared video camera with a temperature sensitivity of at least 50 mK, a lens of at least 32° x 23°, a matrix of at least 160 x 120 pixels, and a thermogram resolution of at least 320 x 240. With the help of a hinged mount the lens of the infrared video camera is directed perpendicular to the surface of the test object. The average temperature of the diagnostic signal from the undercured polymer binder will be ≈ 33°С at the average temperature of basalt plastic ≈ 32°С. The analysis of the obtained results is carried out with the help of special software by constructing histograms of the temperature distribution in given contours or along the lines of thermograms.

Example 2

An example of the implementation of the device is the implementation of infrared thermography for the presence of an undercured connecting blade of a gas turbine compressor (object of control) made of basalt plastic, the components of which are a biaxial basalt fabric with a 0/90° fiber reinforcement direction and epoxy resin. The blade, preheated to a temperature of ≈ 33°C, is placed on the frame of the device. In the area where the blade is located, with the help of two electromagnets located on both sides of the test object, a constant magnetic field with a strength of 68 A/cm is created. Adjustment of the location of the electromagnets relative to the object of control is carried out by moving them along the guides and along the slats. Under the influence of a constant magnetic field, orientational phenomena are created in a solid polymer, which make it possible to determine the temperature boundary between zones with different degrees of molecular order. Registration of the temperature diagnostic signal from the control object is carried out using an infrared video camera with a temperature sensitivity of at least 50 mK, a lens of at least 32° x 23°, a matrix of at least 160 x 120 pixels, and a thermogram resolution of at least 320 x 240. With the help of a hinged mount the lens of the infrared video camera is directed perpendicular to the surface of the test object. During cooling, the average temperature of the diagnostic signal from the undercured polymer binder will be ≈ 32°C, while the average temperature of the basalt plastic is ≈ 31.4°C. The analysis of the obtained results is carried out with the help of special software by constructing histograms of the temperature distribution in given contours or along the lines of thermograms.

Claims (1)

A device for infrared thermography of polymer composite materials in a magnetic field, containing a frame for mounting an object of control with a tripod with an infrared video camera and guides placed on it, on which bars with electromagnets are installed with the possibility of providing longitudinal movement, moreover, the electromagnets are located on the bars opposite each other each other on both sides of the frame with the ability to move along the frame, as well as towards each other and in the opposite direction, and the infrared video camera is mounted on the transverse rod of the tripod by means of a swivel joint, which is movable in the vertical direction to ensure the optimal focal length for recording thermal diagnostic signal from the control object.

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