SU1075143A2 - Ultrasound visualizer - Google Patents

Abstract

1, VISUALIZER ULTRASOUND for auth. No. 1032408, about tL, and in that, in order to increase the sensitivity, it is provided with an ultrasound absorber layer arranged on the other side of the liquid crystal film made by -® Diz material. with an ultrasound absorption coefficient greater than that of the gas in which the ultrasound propagates, and a head impedance close to the wave impedance, the gas a. 2. The visualizer according to claim 1, distinguishes the yen in that the absorber layer is a gas filled ohm cuvette, the bottom of which is made of a sound-transparent film. 3.Vizualizator on PP. 1 and 2, characterized in that the cuvette is made with the possibility of changing its height, 4. Visualizer according to claim 1, characterized in that the layer is absorbed (g ultrasound titanium made of fabric, CO or cloth type. CZ

Description

The invention relates to visualization tools for oscillatory processes and ultrasonic fields in gases and can be used for nondestructive testing of materials and products. According to the main auth. No. 1032408, an ultrasound visualizer is known that contains a temperature-sensitive liquid crystal film and its translucent thermally stable buffer 1 is installed on one side. However, this visualizer has a non-optimal sensitivity value in terms of ultra sound and has a small resolving power, since it has a thermal field corresponding to the ultrasound field under investigation, and acting on the temperature-sensitive liquid crystal film, is created in the entire gas layer between the liquid crystal film and ultrasound emitting surface, i.e. The main absorber of the ultrasound under investigation is the entire gas layer. However, the gas filling the space in which the investigated ultrasound field propagates (usually air) has a small factor that absorbs the ultrasound and therefore the absorption of ultrasound energy in it. gas, are small. In addition, the non-optimal sensitivity in intensity of the ultrasound is also due to the fact that the visitor does not provide for tuning to the resonant absorption of ultra sound in a gas layer heated by the absorbed energy of ultrasound. This is equivalent to the absence of adjustment to the optimal image of the ultrasonic field, since the sensitivity of the ultrasound intensity is related to the visualizer's seeking ability. In addition, since the main absorption of ultrasound energy occurs in the gas layer between the liquid crystal plate and the ultrasound radiating surface, and the visual cinema film of the visualizer captures the thermal field created by the absorbed energy of ultrasound in this gas layer, the effect of the visualizer is related to its location and distance radiation from an ultrasound-emitting surface. At relatively large distances, the liquid crystal film is. From the ultrasound emitting surface of the ultrasound radiator, the compliance of the structure of the thermal field detected by the liquid crystal film with the structure of the ultrasonic field creating it is disturbed. The aim of the invention is to increase the sensitivity. This goal is achieved by the fact that an ultrasound imager containing a temperature-sensitive liquid crystal film and a translucent thermostable buffer mounted on it is provided with an ultrasound absorber layer on the other side of the liquid crystal film made of a material with an ultrasound absorption coefficient greater than that of the gas in which it is distributed ultrasound, and head resistance close to the wave resistance of the gas “In addition, the ultrasound absorber layer is represented by T is filled with a gas cell whose bottom is made of zvukoprozrgo1chnoy film. The cuvette can be made with the possibility of changing its height, and the ultrasound absorber layer i can be made of cloth like cloth. FIG. 1 shows a diagram of the design of the visualizer with an ultrasound absorber layer; in fig. 2 diagram of the visualizer with a layer of ultrasound absorber, made in the form of a gas-filled cuvette; in FIG. 3 is a diagram of an ultrasound visualizer with an ultrasound absorber layer in the form of a gas-filled cuvette configured to change its height. The ultrasound visualizer contains a temperature-sensitive liquid crystal nJieHKy 1, a translucent thermostable buffer 2 installed on one of its surfaces, and an ultrasound absorber layer 3 installed on its other surface, as well as a source of light 4 placed on the side of buffer 2. On the same side is the recorder 5 image. The ultrasound absorber layer 3 can be made in the form of a curtain of b (Fig. 2), the bottom 7 of which is made in the form of a sound-transparent film. The cuvette b is filled with gas 8. In addition, cuvette 6 (Fig. 3) can be made with the possibility of changing its height, for example, in the form of a telescopically connected bottom 7 and shell 9, which has a nozzle 10 for connection to the air line (not shown). Providing the visualizer with the ultrasound absorber layer 3 enables the visualizer to work outside its connection with the ultrasound-emitting surface, independence from the gas in which the ultrasound propagates, and the possibility of selecting the desired properties of the ultrasound absorber, ensuring optimal visualizer performance. The ultrasound absorber layer 3 must be of the same thickness and located on the liquid crystal film 2 parallel to it with the side exposed to the ultrasound, which ensures that the structure of the thermal field in the absorber, the fixed field in the absorber fixed by the liquid crystal 2 matches the structure of the ultrasonic field creating this thermal field . Making the ultrasound absorber layer from a material with an ultrasound absorption coefficient greater than that of a gas in which the ultrasound propagates provides a greater absorption of ultrasound by the absorber than a gas in which the ultrasound propagates, and hence more heat of the absorber, which leads to increase the sensitivity and resolution of the visualizer. The implementation of the absorber layer 3 from a material with a wave impedance close to the wave impedance of the gas in which the ultrasound propagates ensures that the ultrasound enters the absorber. Making the ultrasound absorber layer in the form of a cuvette 6 allows, by filling the cuvette with gas, a gas absorber layer with an impedance close to the impedance of the gas in which the ultrasound propagates, as well as changing the characteristics of the absorber layer, changing the gas filling cuvee tu. The implementation of the bottom 7 of the cuvette 6 in the form of a thin sound-transparent film ensures the passage of ultrasound into the gas of the cuvette, since the film for ultrasound is acoustically transparent. In this case, the liquid crystal films of the visualizer ensure the fixation of the thermal floor in the absorber created by the ultrasound. The parallelism of the ultra-sounding cell wall of the cuvette to the liquid crystal film of the visualizer ensures that the thickness of the ultrasound absorber layer is the same. Performing a cuvette b with a potential for changing its height provides the ability to change the thickness of the absorber layer. The shell 9 of the cuvette b pneumatically drives the bottom 7 of the cuvette while maintaining its parallelism to the liquid crystal film 1, while also changing the distance between them, which provides a change in the thickness of the ultrasound absorber layer, which, in turn, makes it possible to tune the visualizer to resonant absorption of ultrasound in the layer of the absorber. Lastly, it increases the sensitivity of the visualizer, improves the image quality of the ultrasonic field, increases the resolution due to the decrease in response time and the ability to adjust the visualizer to the optimal image of the ultrasonic field. Performing an ultrasound absorber layer from a cloth like cloth provides, for simplicity of design, the incorporation of ultrasound into the absorber layer and greater absorption of ultrasound in it, and hence more heating of this layer than the r-ase layer in which ultrasound propagates. Such a layer of ultrasound absorber is advisable to use when it is not necessary to change the characteristics of the absorber layer. In the embodiment of the specific embodiment of the visualizer, the temperature-sensitive liquid crystal film 1 is a film with a thickness of 160 µm, consisting of an inner layer of cholesteric ary liquid crystal mixed with polyvinyl alcohol. In order to better observe the image of the thermal field on the surface of the liquid-crystal film 1 in reflected light, its surface irradiated by ultrasound is made translucent (black). The operating temperature range of the liquid crystal film 1 is in the range of 25.5-30.5 ° C, in which the color on the observed surface in reflected white light is measured from red to violet depending on temperature, the passage of all the colors of the visible spectrum. At temperatures below 25 and above 30.5s, the color of the observed film surface is black. The translucent thermostable buffer 2 is made in the form of a cuvette filled with a liquid, such as water, the temperature of which is established and maintained constant by means of a thermostatic buffer 2 liquid connected to the cuvette thermostat (not shown) through which the filling cuvette (not p6 kanaza) of translucent thermostable buffer 2 flows. The light source 4, illuminating the observed surface of the temperature-sensitive liquid-crystal film 1, is either ambient light or a special illuminator, such as a glow lamp. The registrar 5 displays the pictures of the ultrasound field on the surface of the liquid crystal film.

1 can serve either an eye of the observer, or a special device, for example a photo or movie camera, a photoelectronic or receiving television or a special device.

The ultrasound absorber layer 3 in the variant of a video beaker with a cloth absorber layer is made of 0.5 mm thick tissue attached to the surface of the liquid crystal film 1 irradiated with ultrasound.

In the embodiment of the layer of ultrasound absorber in the form of a cuvette.6, filled with gas 8 (Fig. 2 and 3), the bottom 7 of the cuvette 6 is made of a dacron film 5 microns thick. When the ultrasound field under study is distributed in the air, the absorber gas 8 of ultrasound filling the cuvette 6 is carbon dioxide (COj), which has an absorption coefficient of ultrasound much higher than that of the spirit.

The shell 9 of the cuvette b (Fig. 2 and 3) is made of any non-permeable gas and material that does not react with it.

In the embodiment of a cuvette B with a change in height (Fig. 3), the shell 9 is made, for example, in the form of two cylinders entering each other or in the form of a bellows. A drive that changes the frequency of the cuvette 6 can be an air line with the same absorbing gas 8.

The visualizer works as follows.

The visualizer is placed in a gas in which the ultrasound field under study is propagated, so that the ultrasonic wave normally falls on the ultrasound absorber layer 3. Passing through this layer, the ultrasound is partially absorbed in it and creates in it a thermal field corresponding in structure to the ultrasonic field that creates it, i.e. energy distribution along the front of the incident ultrasonic wave. The heat field in the ultrasound absorber layer is recorded by the temperature-sensitive liquid-crystal film 1 by a local change in its color in reflected light in accordance with; iocal temperature of each section of the heat floor in the layer 3 absorber of ultrasound. As a result on

The observed surface of the temperature-sensitive liquid crystal film 1 produces a color image of the thermal field corresponding to the distribution of the ultrasound intensity along the front of the ultrasonic wave, which is either observed visually or recorded by the corresponding recorder 5.

To ensure optimal operation of the visualizer, t, e.

its maximum sensitivity and minimum response time, the temperature of the liquid crystal film 1 and the ultra sound absorber layer 3 are set and maintained by means of a thermostable buffer 2 at the lower limit of the operating temperature range of the liquid crystal film 1.

0 In the variant of the visualizer with a layer 3 absorber of ultrasound of varying thickness (Fig. 3), to ensure maximum sensitivity and cutting ability of the visualizer, it is tuned to resonant absorption of ultrasound by the layer of absorber 5. To this end, the thickness of the ultrasound absorber 3 is changed and tuned produced

Q either according to the optimality of the visual picture of the ultrasound field given by the visualizer, or according to the table attached to the visualizer or the calibration curve of the dependence of the thickness of the ultrasound absorber layer 3 on the ultrasound frequency at which its absorption by the absorber layer 3 will be resonant.

The use of the invention allows to increase the sensitivity of ultrasound intensity, increase the resolution and image quality. In addition, the visualizer provides the ability to

working outside of it with an ultrasound-emitting surface. This improves the accuracy of the measurements made by the visualizer, in particular, when using the visualizer in non-destructive ultrasound testing, it allows the use of ultrasonic measuring devices of lesser power, controlling the thickness of a thinner, and detecting smaller defects.

This also enhances the express control.

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Claims (4)

1. VISUALIZER ULTRASOUND- SC on autosw. No. 1032408, whereby, in order to increase sensitivity, it is equipped with an ultrasound absorber layer located on the other side of the liquid crystal film made of a material with an ultrasound absorption coefficient greater than that of the gas in which the ultrasound propagates, and a head resistance close to wave impedance ^ gas a. 2. Visualizer by π. 1, wherein u ^_ I c and d in that the absorber layer is filled _gaz th cell, the bottom of which is made of zvukoproerachnoy film. 3. The visualizer according to paragraphs. 1 and 2, characterized in that the cuvette is made with the possibility of changing its height. 4. Visualizer by π. 1, characterized in that the ultrasonic absorber layer is made of woven fabric, neither of type of cloth. FIG. 2 ^ niorns