RU18538U1 - DEVICE FOR DETERMINING PHYSICAL AND MECHANICAL CHARACTERISTICS OF STRUCTURE OF FABRIC UNDER LOAD - Google Patents

Abstract

A device for determining the characteristics of the structure of tissues under load, containing rigid and elastic shafts, means for control, characterized in that the latter is made in the form of two optical fibers, each of which is placed so that one end of the optical fiber is located along the axial line of the shaft, and the other is radial, while the radial ends of the optical fibers are aligned.

Description

i and o in t i i and t I

Device for determining physical and mechanical characteristics

the structure of the tissue nodes load.

The utility model relates to the textile industry, and in particular to devices for determining changes in the structure of the fabric by the load, and can be used in roll bunks (modules) for various purposes.

In the field of investigation of the contact zone of the shafts, a device is known that works by the method of photoelasticity I, which makes it possible to evaluate their stress state based on the phenomenon of interference but the nature of the arrangement of light and dark bands on the screen. The device contains 2 disks, one of which is made of SKU-6 poturethane with a diameter of 100 mm, paired with a hard drive made of organic glass, mounted on a special stand. A stand with a pair of disks is located between the polarizer and the analyzer of the polarization-optical installation. The load on the discs is created using a lever push device. The resulting polarization picture is photographed on a film, isoclines are obtained. The lines of the combined field of isoclines and stripes are transferred from the film to the sheet of paper through

MTZh D06B

G01B9 / 00

enlarger. The data obtained are processed by the difference method of tangential nanowires.

A device for measuring the tangential forces in the contact zone of the rolls with the help of electric tensometers was adopted for nrototin. The device contains two shafts, one of which is rigid, and two sectors (movable and fixed), the second has an elastic coating. On the movable sector of the rigid shaft, there is a nlanca with a bolt on which electrical resistance tensometers are glued. Strain gauges record the force with which the sectors act on each other; electrical pulses are removed by a thin-film device and fed through an amplifier to an oscilloscope. The elastic shaft is clamped by a lever system. The rigid shaft is driven by an adjustable hydraulic drive. The countdown of the impact of one sector on another is carried out by the position of the light bunny on the oscilloscope screen 2.

A disadvantage of the known technical solutions is the lack of a visual image of the structure of the fabric directly under load from the front and back sides.

The technical result is to increase the quality control of the deformation of the material and the contact parameters while reducing the time for processing the obtained experimental data and the possibility of using the device for almost all types of textile materials.

The technical result is achieved due to the fact that in the device containing two shafts (rigid and elastic) and means for monitoring, according to the model, the monitoring means is made in the form of two optical fibers, each of which is placed in such a way that one end of the optical fiber is located along the axial line of the shaft, and the other radially, while the radial ends of the optical fibers are aligned.

Figure 1 presents a diagram of the inventive device, figure 2, Fig.Z - attachment points of the screens of the optical fibers.

The device (figure 1) contains a roll module, consisting of metal 1 and elastic (coating - rubber or wool paper) 2 shafts in which two optical fibers 3 are installed.

One end of the optical fiber is located along the axial line of the shaft, which ensures the rotation of the fiber without its radial displacement, this eliminates the synchronization mechanism when capturing the image. The other end is located radially to the surface of the shaft. Bushings 4 for fixing the ends of the optical fibers, and lenses of optical devices 5 for fixing the image.

The device operates as follows: on shafts 1 and 2, using hand presses containing indicators, the required load is set. Then, with the help of an electric drive, the device is set in motion and the processed material is transported to the contact zone

shafts 1 and 2, thereby being subjected to pressure treatment. An element of materials that is under load in the area of the lenses of the optical fibers 3 is projected through its fibers in the form of a true image onto the lens of a photo or movie equipment. The image is transmitted through optical fibers installed in metal and elastic shafts, from the surface of the front and back sides of the material. The received image signals of the surfaces of the material are recorded on the film of the optical device.

From a photograph of a tissue fragment, the diameters of the threads and the distance between them are measured taking into account the optical magnification, but the results are used to calculate the characteristics of the fabric: density, filling, filling, etc. To take into account the effect of the loads on the specified characteristics of the fabric, measurements are made at loads from O to JMP.

Sources of information irrelevant:

1.Kuznetsov G.K. Application of the photoelasticity method to study contact stresses in rolls with a non-rigid coating. // News of universities. Technology of the textile industry. No. 2, 1968 S. 139-142.//

2.Taleporovsky Yu.L. An experimental study of the contact area of two shafts. // News of universities. Technology of the textile industry. No. 6, 1970 S. 140-142.//

Claims (1)

A device for determining the characteristics of the structure of tissues under load, containing rigid and elastic shafts, means for control, characterized in that the latter is made in the form of two optical fibers, each of which is placed so that one end of the optical fiber is located along the axial line of the shaft, and the other is radial, while the radial ends of the optical fibers are aligned.