RU78565U1 - OPTICAL AND TELEVISION DEVICE FOR DISPLAYING SURFACE DEFORMATION LOCALIZATION ZONES - Google Patents

Abstract

The inventive utility model relates to devices for the study and control of stress-strain states, process control during the deformation transformation of solids, flaw detection and mechanical testing of materials. The technical problem solved using the proposed technical solution is to create a device for the study and control of stress-strain states of solids. The technical result obtained as a result of the implementation of the utility model is to provide visualization of non-standard samples of sizes from 100 to 10 mm with high accuracy of the display of strain localization zones. The specified technical result in the implementation of the claimed technical solution is achieved by the fact that the inventive optical-television device contains a source of coherent radiation and a computer-associated surface teleregistration system. A feature of the device is that it additionally contains a controller controlled by a computer and connected to all nodes of the device, as well as a module for managing changes in the parameters of the teleregistration system associated with the controller.

Description

The inventive utility model relates to devices for the study and control of stress-strain states, process control during the deformation transformation of solids, flaw detection and mechanical testing of materials.

A device is known [SU 1126812 A1, 1984] for measuring the deformations of diffusely reflecting objects, containing a sequentially installed source of coherent radiation, a banner with a drive, a shear interferometer, consisting of two parallel diffraction gratings with parallel oriented strokes, two photodetectors and a phase meter connected to the outputs of photodetectors, however, it is additionally equipped with a heterodyne shear interferometer with an aperture diaphragm installed between the source of coherent healing and the transparency mine, the magnitude of the shift of which is equal to the diameter of its aperture diaphragm, the transparency is made in the form of a speckle photograph with a spaced speckle structure modulated by interference bands oriented perpendicular to the displacement vector of the spaced speckle structure and set at a Bragg angle to the optical axis so that the direction of shear the heterodyne interferometer lies in the same plane as the displacement vector of the speckle diversity structure, the projection of the displacement vector in the direction perpendicular to the optical axis of the devices and in the shear plane of the heterodyne shear interferometer, it is equal to the magnitude of this shear, the gratings of the shear interferometer are installed parallel to the transparency plane so that the strokes of the gratings are oriented perpendicular to the displacement vector of the speckled speckle structure, one of the photodetectors is installed during the radiation transmitted through the transparency without deviation, and the other the photodetector is installed in the course of radiation scattered on a banner.

However, with a sufficiently high accuracy of the known device, visual visualization in real time is not provided.

A device for determining deformation [Optical-television methods for the study and diagnosis of materials at the mesoscale // Physical mesomechanics and computer-aided design of materials: 2 tons / V.E. Panin,

V.E. Egorushkin, P.V. Makarov et al. - Novosibirsk: Science. Siberian Publishing Company RAS, 1995. - T.1. - 298 p.], One of the functions of which, in particular, is the visualization of surface deformation fields. The device includes a lighting system, a television camera in series, a digital video capture device, and a computer. The latter is endowed with the functions of storing digital video frames corresponding to the reference and deformed states of the surface, and calculating for them the field of the selective cross-correlation coefficient (CWC) with its subsequent numerical differentiation to obtain and display the deformation field.

The disadvantage of this device is its implementation of the mapping of localization zones of deformation on the basis of single measurements of HVAC subject to statistical spread due to the limited size of the correlation windows used in the measurement.

A device is known that implements a decorrelation method for visualizing deformation localization zones described in [Gorbatenko V.V., Polyakova S.N. and Zueva LB, The method of computational decorrelation of video images with speckle structure and equipment for visualizing strain localization zones in real time / Full-text database "Scientific and technical developments of Russia". - Inform. sheet 72-044-2000]. The device comprises a laser, an optical illumination system of a controlled surface, a television camera, a digital video capture device, a computer and a monitor connected in series. The computer implements the functions of managing video input, storing digital video frames, computing cards of a selective mutual decorrelation coefficient (VKVD) between time-spaced video frames with subsequent storing and visualizing them on the monitor screen of the calculation results or output (for example, to a file for subsequent display by other technical means). The repetition rates of video capture, calculations and visualization, the size of the correlation window and the time shift of the video frames subjected to correlation analysis are subject to preliminary program determination.

The disadvantage of this device is its inability to perform statistically independent measurements of the VVD for slightly deforming, closest in time observations due to the high correlation of the speckle structures observed in this case, formed under constant illumination.

Closest to the claimed is an optical television device [RU 2192621 C2, 2002], containing a coherent radiation source, an optical illumination system of a controlled surface, a series-connected surface teleregistration system, a digital video capture device and a computer connected to the display. The surface teleregistration system is capable of simultaneously recording a combination of its equally diffraction limited images with statistically mutually independent speckle structures implemented by multi-angle and / or color television photography options.

However, it is possible to use the known device only for the study of samples of standard sizes, namely, a length of 100 mm, used on an INSTRON testing machine.

The technical problem solved using the proposed technical solution is to create a device for the study and control of stress-strain states of solids.

The technical result obtained as a result of the implementation of the utility model is to provide visualization of non-standard samples of sizes from 100 to 10 mm with high accuracy of the display of strain localization zones.

The specified technical result in the implementation of the claimed technical solution is achieved by the fact that the inventive optical-television device contains a source of coherent radiation and a computer-associated surface teleregistration system.

A feature of the device is that it additionally contains a controller controlled by a computer and connected to all nodes of the device, as well as a module for managing changes in the parameters of the teleregistration system associated with the controller.

In addition, the controller is an electronic board that works directly with a computer through a serial port.

In addition, the module for managing changes in the parameters of the teleregistration system is configured to register the working area of the sample from 100 to 10 mm while maintaining the resolution.

In addition, the surface teleregistration system is a digital video camera.

In addition, a helium-neon laser was chosen as a source of coherent radiation.

The proposed device is illustrated by the drawings presented in figure 1 - figure 3.

Figure 1 - presents a block diagram of the proposed device.

Figure 2 - shows a diagram of the operation of the device.

Figure 3 - shows a speckle on the surface of the test sample (object).

In Fig. 1, the block diagram of the device contains a controller 1 that controls the nodes of the device, a module for controlling changes in the parameters of the teleregistration system 2, a coherent radiation source 3 for illuminating the sample (object), a teleregistration system for the surface (video camera) 4, which records speckles on the surface of the sample (object ) and computer 5.

The device is based on the following principle - the object is illuminated by a scattered beam of coherent radiation, thereby creating a speckle pattern on the surface of the object. Speckles are “attached” to the surface. When the object is deformed, the speckles begin to change their position along with the deformation of the surface of the object, and the video camera, in turn, registers these changes (frame by frame). Therefore, differences in adjacent frames give a picture of the changes that have occurred on the surface of the object.

The device consists of a firmware and a processing program.

A laser was used as a source of coherent radiation.

The controller is an electronic board that works directly with the computer via the RS 232 serial port.

The control module for changing the parameters of the teleregistration system is an optical-mechanical unit and is configured to register the working area of the sample from 100 to 10 mm while maintaining a resolution of 1280 pixels in length.

The surface teleregistration system is a black-and-white digital video camera with a high degree of brightness gradation - 16 bits with a low noise figure and a high data transfer rate.

A helium-neon laser was chosen as a source of coherent radiation.

The device operates as follows (Figure 2).

The object is illuminated by a coherent radiation source (helium-neon laser 3, the lens serves to create uniform illumination of the object, the module for controlling changes in the parameters of the teleregistration system 2 changes the aperture size and provides an optical increase in the working surface of the object (in Fig. 2, the position of the maximum increase is shown by dashed lines, possibly tenfold increase.) The parameters of the teleregistration system are configured before the start of the experiment. Digital camera 4 transmits information through the interface IEEE 1394 to computer 5, where the information is stored either as a video stream or as a set of photos in BMP format.The shooting frequency depends on the experimental conditions.The camcorder allows shooting at up to 5 times per second, with a resolution of 1280 × 1024 pixels. the device is implemented through the serial port RS 232.

The processing program is based on the brightness subtraction of two adjacent frames: the next frame is subtracted from the previous frame. As a result, changes in the location of speckles on the surface of the sample, shown in FIG. 3 (a, b, c, d, e), are saved, and the result can be saved as a video file.

Accordingly, a very clear and effective visualization of the localization of plastic deformation of the studied sample (object) is obtained.

Device Specifications:

Overall dimensions of the device are 670 × 180 × 170. The device has a tenfold increase, it is possible to work with objects from 10 mm to 100 mm in length, respectively, a resolution of 1280 pixels for the entire length. The shooting speed is 5 frames per second at a resolution of 1280 × 1024.

Claims (5)

1. Optical-television device for displaying zones of localization of surface deformation, including a coherent radiation source and a computer-based surface teleregistration system, characterized in that it further comprises a computer-controlled controller and connected to all nodes of the device, as well as a module for managing changes to the parameters of the teleregistration system associated with the controller. 2. Optical television device according to claim 1, characterized in that the controller is an electronic board that works directly with a computer through a serial port. 3. The optical television device according to claim 1, characterized in that the module for managing changes in the parameters of the teleregistration system is configured to register the working area of the sample from 100 to 10 mm while maintaining the resolution. 4. Optical television device according to claim 1, characterized in that the surface teleregistration system is a digital video camera. 5. The optical television device according to claim 1, characterized in that a helium-neon laser is selected as a source of coherent radiation.