DE1006166B - Method for measuring distances by means of sound waves, in particular ultrasonic waves and apparatus for practicing the method - Google Patents

Description

Method for measuring distances by means of sound waves in particular Ultrasonic waves and device for practicing the process Addendum to patent 952 943 The main patent 952 943 relates to methods and devices for Measurement of distances by means of standing sound waves, in particular ultrasonic waves, and aims to avoid the inaccuracies in the scale division, which is what happens that the sound wave in a medium whose length is a multiple of 2/2 is generated and that A / 2 or a multiple of 2/2 is a unit of division represents between a start and an end measurement mark, so that each a maximum or a minimum of the standing wave pass through the start and end measurement marks, and that the maxima or minima of the standing wave to produce pitch intervals individually or for setting measuring sections composed of graduation intervals summed up, to measure the standing vibration state was it is proposed here in particular that the ultrasonic field be in a magnetic rod or tube is generated and that the mechanical vibrations of the elementary magnets are inductively sampled within the standing sound wave.

Another embodiment of the method according to the main patent exists in that the ultrasonic field is generated in an optically transparent medium, where the smallest measuring distance of the periodic return of a sound field quantity, for example pressure or velocity or refractive index, corresponds to that visited or made visible and transmitted.

The invention is a further development of this method and exists that for this purpose transparent, elastic birefringence exhibiting media, for example glass, are used, the elastic of which is generated by the sound field Birefringence visible and photoelectrically measurable with the help of polarized light is made. If one shines through a transparent one vibrating in the ultrasonic field Medium, for example a vibrating glass rod perpendicular to the direction of propagation the ultrasonic waves with polarized light, so one can with the interposition of an analyzer, the vibration maxima and minima in the medium are directly visible and make measurable. They arise, for example, as a result of at a distance of 2/2 adjacent luminous measuring elements, their training with subjective Observation with the interposition of suitable graticules, as is also the case with other optical measurements is common, can be used for length measurement can or their increase and decrease in brightness with the help of a photoelectric Energy comparison can be used for length measurement. This method In addition to its simplicity, it has the main advantage that one disturbances either as a result a change in the frequency emitted by the transmitter crystal or as a result of insufficient Immediately notice and localize the coupling of the oscillating medium to the transmitter crystal can, since with this method the vibrating medium is observed directly and not only, as is the case with other methods, e.g. B. in the process of secondary interference, is the case, brought about by the vibrating medium at a certain, but mostly outside of the vibrating medium generated point of the optical beam path Change in the appearance of light that arises there.

The invention, insofar as it relates to the device for exercising the Method is characterized in that an optically transparent, elastic birefringence having a scale, preferably made of glass, on one End carries the quartz oscillator, which is attached to a holding device, and that an optical system is arranged perpendicular to the axis of the glass rod, which consists of the light source, the polarizer, the condenser, the objective and the analyzer exists and shines through the glass rod with parallel light, and that in the plane of projection of the lens has a gap system with at least two gaps and two behind them equivalent photocells with connected to a measuring bridge Display device are arranged and that the photoelectric system to the glass rod or conversely, the glass rod for scanning the standing wave generated in the glass rod against each other are movable.

The object of the invention is shown in the drawing in an exemplary embodiment shown schematically greatly enlarged. Here 1 is an exactly prismatic glass rod, whose length is equal to a multiple of half the sound wavelength passing through an oscillating crystal 2 is excited to oscillate.

The frequency of the quartz crystal is chosen so that in the glass rod standing vibrations are generated, as indicated by the hatching. The narrowing lines indicate the places of the pressure maxima between them the pressure minima are. The distance from one pressure maximum to the other is as well as half a wavelength from one pressure minimum to the other, i.e. i / 2. The vibration phenomenon is in reality usually more complicated, but changes this has nothing to do with their principle. The quartz oscillator 2 is on a holding device 3 cemented. It also has a conductive coating 4. The holding device 3 and the covering 4 are connected to the high-frequency generator via the lines 5 and 6 7 in connection, so that after switching on the high-frequency generator 7 of the quartz oscillator 2 is made to vibrate. The direction of propagation of the sound waves in the glass rod takes place vertically upwards, parallel to the axis 25 of the glass rod. Perpendicular to Axis 25 of the glass rod is an optical system that consists of the light source 8, the polarizer 9, the condenser 10, the objective 12 and the analyzer 13 consists. The arrangement is made so that the glass rod with parallel light is irradiated, wherein the lens 12 the glass rod in the plane of the blend system 15 images. The polarizer 9 is rotated so that the light that has emerged from it oscillates in a plane which is inclined by 450 to the axis 25 of the glass rod, as indicated by the direction of the arrow 11. The analyzer 13 is located in a crossed 900 position to the polarizer 9 (arrow direction 14), so that in the The field of vision is dark if there is no birefringence in the glass rod, d. H. when the tension-free glass rod does not vibrate. After switching on the ultrasonic transmitter with a precisely tuned frequency is created by the standing sound waves in the glass rod elastic birefringence, which is on a projection plane at the location of the fissure system 15 as a sequence of light and dark spots at a distance of a quarter of the ultrasound wavelength represents in the glass rod 1 multiplied by the image scale of the lens 12. It is not necessary here for the image brightness to be perpendicular to the axis 25 is uniform, but it can according to the vibration state of the glass rod 1 also occur in the extension 26 oscillation maxima and minima, so that in the extension 26 are several sequences of luminous discs next to each other, the in the direction of the axis 25 is always the distance of half a sound wavelength from one another exhibit.

The focal length of the lens is used to increase the accuracy 12 briefly, as shown in Fig. 1, only a part of the Oscillation figure arising within half a sound wavelength in the glass rod are mapped, so that when you need to measure the displacement of the entire optical systems 8, 9, 10, 12, 13, 15, 16 parallel to the axis 25 of the glass scale alternately perceives an increase and decrease in brightness in the image plane.

This increase and decrease in brightness can be seen according to the thought the invention expediently measure photoelectrically. For this purpose one assigns in the Image plane, d. H. close behind the fission system 15 two photoelectric cells, or, as shown, a junction cell 16 with a gap-shaped interruption the barrier. Because of the two separate layers 17 and 18 give rise to two separate cells, corresponding to their exposures over the lines 19a and 20 or 19b and 20 different high voltages into the electrical Send measuring system. This electrical measuring system consists of the measuring bridge 21 expediently with electrical amplification and the display device 22, the rash then the Size of the exposure difference on the photoelectric cells 16-17 and 16-18 indicates.

To refine the measurement one arranges according to the thought of the invention in front of the two photoelectric cells, a cleavage system 15 which consists of the two columns 23 and 24. Choose the distance between the two columns 23 and 24 equal to a quarter of the sound wavelength in the glass rod 1 multiplied with the image scale of the objective 12, one obtains on one of the two Photocells greatest darkness when the other photocell is extremely bright, so that every extreme position, i.e. the maximum deflection of the pointer of the measuring instrument 22 the passage of the middle position between a vibration maximum or

- indicates the minimum of the glass rod 1 through the axis of the optical system, the extreme position of the pointer then being reached towards one and the same side becomes when the optical system 8, 9, 10, 12, 13, 15, 16 a distance equal to that has traversed half the sound wavelength in the glass rod 1 parallel to the axis 25.

However, you can also according to the idea of the invention two columns 23 and 24, as shown in the drawing, in a smaller one Arrange a distance from each other, then the zero position of the pointer of the instrument 22 each the passage of a vibration maximum or a vibration minimum of the glass rod 1 by the optical axis of the optical system, so that at Movement of the optical system parallel to the optical axis 25 by a quarter of the Sound wavelength in the glass rod 1 just two zero positions of the pointer of the instrument 22 can occur. According to the concept of the invention, is particularly favorable sinusoidal course of the light energy the measurement with the help of the zero position of the pointer instrument 22 when the two gaps 23 and 24 again have a distance equal to the sound wavelength have in the glass rod 1 multiplied by the magnification of the lens 12, there then on each of the two photocells both in the setting to the vibration maximum how energies of equal size fall in the setting at the vibration minimum, so that the measurement of the vibration maximum as well as the measurement of the vibration minimum due to the equality of the energy falling on the photocells with the same optimum electrical accuracy takes place.

In this way you will also meet the steepest parts Increase or decrease in light energy and thus works with the greatest sensitivity.

If, however, a different form of vibration arises in the glass rod than one sinusoidal or a power of the sinusoidal, for example, are the luminous ones Areas large in proportion to the dark areas, so become according to the thought the invention, the two columns 23 and 24 arranged at such a distance that in each case when setting either to the oscillation maximum or to the oscillation the points of steepest rise or fall in light are recorded, in which case only the vibration state assigned to the gap position for setting, d. H. either the vibration maximum or the vibration minimum is used.

In addition, it can be advantageous from a metrological point of view, over several oscillation maxima or to measure vibration minima, d. H. for example sinusoidal The course of the oscillation in the glass rod equals the distance between the two gaps 23 and 24 three quarters, five quarters, seven quarters etc. of the sound wavelength in the glass rod 1 multiplied by the magnification of the lens 12.

You can also have a system of several in front of each of the two photocells Make gaps that each multiply by half the sound wavelength in the glass rod 1 with the magnification of the lens 12 are spaced apart, so that both Gap systems with a sinusoidal course of the oscillation by a quarter, three quarters, five quarters etc. of the sound wavelength in glass rod 1 multiplied by the image scale of the lens 12 are offset from one another. With a non-sinusoidal course of the The oscillation of the two gap systems must be offset against each other accordingly be that the places of the steepest fall and rise in light are recorded. on In this way, several illuminated areas can be added to the photocells, in order to obtain a greater luminous flux, which depends on the illuminated area is. The wavelength in the glass rod can be, for example, 1 mm if it is is about transferring metric divisions.

Claims (20)

PATENT CLAIMS 1. Method for measuring distances by means of standing Sound waves, in particular ultrasonic waves, of the wavelength A, at which the Sound wave in an optically transparent medium, the length of which is a multiple of A / 2, and Å / 2 or a multiple of A / 2 is a unit of division represents between a start and an end measurement mark, so that each a maximum or a minimum of the standing wave pass through the start and end measurement marks, and the maxima or minima of the standing wave for establishing pitch intervals individually or for setting measuring sections composed of graduation intervals summed up, according to patent 952 943, characterized in that a optically transparent elastic birefringence exhibiting medium, for example Glass, is used, the elastic birefringence of which is generated by the sound field is made visible and photoelectrically measurable with the help of polarized light. 2. The method according to claim 1, characterized in that the medium a prismatic, cylindrical or tubular body with a preferred longitudinal extension is used, its one axially perpendicular boundary surface is the entry surface represents sound waves traveling parallel to the axis of the body and whose other axially perpendicular boundary surface is the reflector of the sound waves to generate the standing vibration. 3. The method according to claims 1 and 2, characterized in that that a prismatic rod made of stress-free glass is used as the medium. 4. The method according to claims 1 to 3, characterized in that that the light rays emerging from the polarizer of the optical arrangement under swing at an angle of 450 to the axis of the medium and that the analyzer is in a crossed position to the polarizer. 5. Process according to claims 1 to 4, characterized in that that the optical observation and measuring system for measurement parallel to the axis of the Body is moved while the body is stationary. 6. The method according to claims 1 to 4, characterized in that that the body for measurement parallel to its axis with the optical fixed Observation and measuring system is moved. 7. The method according to claims 1 to 6, characterized in that that due to the elastic birefringence caused by the standing oscillation The resulting increase and decrease in brightness is measured photoelectrically. 8. The method according to claims 1 to 7, characterized in that that the photoelectric measurement with the help of two photocells in a bridge circuit is carried out. 9. The method according to claims 1 to 8, characterized in that that each photocell is assigned a light limiting gap. 10. The method according to claims 1 to 9, characterized in that that when observing the zero position of the electrical display device, the distance of the two columns is chosen so that on one the point the steepest rise in light and on the other the point of the steepest fall of light caused by the vibrating The light phenomenon generated by the glass rod is imaged, whereby the measurement is over can extend one or more of the standing vibrations in the glass rod. 11. The method according to claims 1 to 8, characterized in that that each photocell is assigned a gap system, the individual column of which is one Distance of half a sound wavelength in the body multiplied by the image scale the intermediate image of each other. 12. The method according to claim 11, characterized in that upon observation the zero position of the electrical display device so that the two gap systems against each other are offset that with the one the steepest light rise and with the others the points of steepest fall in light caused by the vibrating glass rod generated light phenomenon can be detected. 13. The method according to claims 1 to 12, characterized in that that the two gaps or the two gap systems are offset by a quarter, three quarters, five quarters, etc., of the sound wavelength in the body multiplied with the image scale of the intermediate image exhibit from each other, the measurement by observing the extreme position of the electrical display device is carried out. 14. Device for making graduations with precise intervals for carrying out the method according to claim 1 or one of the following, characterized in that that an optically transparent and elastic birefringence exhibiting scale, preferably made of glass (1), the quartz oscillator (2) at one end, which at one end Holding device (3) is attached, and that perpendicular to the axis (25) of the glass rod an optical system is arranged, which consists of the light source (8), the polarizer (9), the condenser (10), the objective (12) and the analyzer (13) and the Glass rod shines through with parallel light, and that in the plane of projection of the Objective (12) a gap system (15) with at least two gaps (23, 24) and behind these two equivalent photocells with a measuring bridge (21) connected Display device (22) are arranged, and that the optical photoelectric system to the glass rod or vice versa the glass rod for scanning the rod generated in the glass standing wave are mutually displaceable. 15. The device according to claim 1, characterized in that the Gaps (23, 24) of the gap system (15) have a distance equal to a quarter of the sound wavelength in the glass rod (1) multiplied by the magnification of the lens (12). 16. The device according to claim 14, characterized in that the Column (23, 24) of the gap system (15) a distance which is smaller than a quarter the sound wavelength in the glass rod (1) multiplied by the magnification of the Have objective (12). 17. The device according to claim 14, characterized in that the Column (23, 24) are arranged at such a distance that each time when setting either on the vibration maximum or on the vibration minimum the places steepest rise or fall in light can be detected, then for adjustment only the vibration state assigned to the gap position, d. H. either the vibration maximum or the vibration minimum is used. 18. Device according to claims 14 to 17, characterized in that that the gaps (23,24) are arranged so that the measurement over several oscillation maxima or oscillation minima takes place away, so that with a sinusoidal course of the oscillation in the glass rod the distance between the gaps (23, 24) equal to three quarters, five quarters, seven quarters of the sound wavelength in the glass rod (1) multiplied by the image scale of the lens (12). 19. Device according to claims 14 to 18, characterized in that that in front of each of the two photocells (17, 18) a system of several columns th is arranged, which is multiplied by half the sound wavelength in the glass rod (1) with the magnification of the lens (12) are separated from each other. 20. The device according to claim 14 or one of the following, characterized characterized in that the optically transparent, elastic birefringence having Rod on the one hand and the optical photoelectric system on the other hand against each other movable machine parts, for example a guide bed and the one on this vefschieblichen adjustment slide, preferably a machine tool, arranged are.