DE1930111A1 - Optical measuring probe for dynamic distance measurement - Google Patents

Description

Optical measuring probe for dynamic displacement measurement The invention relates to an optical probe for dynamic distance measurement of moving parts with a Light source and a light-sensitive arrangement as well as a multitude of light guides, which allows way-time functions to be carried out contact-free and without being influenced by record the measuring device.

The above-mentioned measuring probe is used to record the curve s = f (t) from preferably small mechanical parts in order to recognize their movement sequences and to analyze them and, if necessary, to tone them with assigned electrical time functions, z. B is related to the current curve of a magnet that moves the part in question to bring, measurements of this kind are necessary in practice to meet the energy demand and course of movement for a desired movement correctly. to control and undesired movement sequences (e.g. vibrations). From the obtained curve s = f (t), which shows the distance covered as a function of time, can furthermore, if necessary, the curves v (t) and b (t), i.e. speed and Derive acceleration as a function of time.

An optical measuring probe that is contactless and without interference of the part to be measured works, is known for position and length measurement (German, Offenlegungsschrift 1 448 394).

It consists of a series of elongated radiation transmission elements, which transmit the radiation over their entire length by multiple internal reflection, wherein the receiving ends of the elements each have an elongated cross section and in a row arrangement with 1 the long sides parallel to each other with narrow Distance next to each other are arranged while the other ends of the elements are each individually opposite radiation receivers, with those of Radiation transmitted to an element excites a single radiation receiver. With this device, it is true that the position and length of a radiation-emitting Body, e.g. B. a red-hot metal sheet, but not the movement of a Measure any mechanical part as a function of time.

For motion recordings on fast mechanisms, an optical one is used Measuring probe based on the principle of the light barrier known (Industrie-Anzeiger, vol. 91, No. 4, pp. 24 to 26). With her, a parallel light beam is drawn through a prism in articulated a measuring gap into which a flag attached to the part to be measured is immersed and fades out more or less large parts of the light. On the other side of the A second prism is located near the measuring gap, which sends the remaining light onto a photocell directs. This device assumes that the part to be measured comes from both sides is accessible; otherwise it must be provided with a rigidly attached flag, which changes the weight of the part and thus its movement. The parallelization of light on the one hand and its concentration on the photocell on the other In addition to the prisms on both sides of the measuring gap, there are other optical systems that make up the probe make it so misshapen that only in easily accessible places, but not inside can be measured by mechanical structures. The aim of the invention is by contrast a non-contact measuring probe that does not affect the test object and which also take measurements in places that are difficult to access or accessible from one side, e.g. Be on one key levers of a keyboard arranged in the midst of a row of further key levers, allowed. According to the invention, this is achieved by an optical measuring probe with a light source, a light sensitive one Arrangement as well as a variety of light guides achieved in that the light guides are combined into two bundles, of which one leads to the light source and the other to the original arrangement, and at the measuring point one light guide each - from the first bundle next to a light guide from the second bundle is arranged linearly.

The light guides can be designed to be flexible so that they can also be guided around corners and through gaps.

The part to be measured is illuminated by the first bundle, and that second guides the light reflected from this part to a light-sensitive arrangement, for example a photocell, photodiode or a photoresistor. Through the linear arrangement of the light guides of both bundles next to each other is on the light-sensitive Arrangement a measured value removable, each of the extent of the straight at the measuring point located part of the test object, provided that the test object opposite his Environment has different reflectivities, since the objects to be measured in However, not all parts ask each other about their ability to reflect stand out from their surroundings, a development of the invention provides that the Moving part to be measured at the measuring point with a defined area from opposite its surroundings with different reflectance or absorption capacities is.

Such an area can simply be glued on a thin white or glossy paper can be created on the measurement object. The acquisition of measured values becomes, since according to the above, the value supplied by the photosensitive arrangement is the Extension of the section just scanned corresponds, especially easy if this paper is not even, e.g. B. is square, but its sections are perpendicular to the Movement weighting results in increasing or decreasing lengths. An embodiment of the Invention is therefore characterized in that the range is different Reflectivity or absorption capacity according to the function to be measured is formed, that is, for. B. to accommodate a linear function triangular, for receiving an angle in the form of a geometric figure with the angle increasing width and to accommodate a quadratic or other nonlinear Function with corresponding non-linear limiting lines.

If such an area cannot be attached to the measurement object, is provided according to another embodiment of the invention that the area different Reflectance or absorption capacity is rectangular and the light guide of one or the other bundle are arranged in such a way that the conductors of the first bundle of lighting led to the measuring point or that through the ladder reflected light guided by the second bundle to the light-sensitive arrangement in the direction of movement of the part to be measured according to the function to be measured increases or decreases.

In each of the above embodiments, one becomes particularly simple Structure of the measuring probe achieved in that, according to a further development of the invention the fibers of a fiber optic known per se are used as light guides.

The accuracy limit of the measuring probe is reached where the resolving power the fiber optics ceases. A further development of the invention exceeds this limit simply by the fact that at the measuring point between the to be measured part and optical means are provided at the common end of both bundles, which Part to be measured or the area on it $ different reflection or map absorption capacity on the common end of both bundles. These additional optical means preferably bring about a magnification of what is to be measured Part or the area located on it have different reflectivity or absorption capacities.

The advantages that can be achieved with the invention are, in particular, that by simple means precise measurements of motion sequences, even on difficult ones accessible places and without interfering with these processes, it is also possible by designing the reflecting or absorbing area accordingly not only linear functions, but also their derivatives and Krels functions can be obtained directly as measured values and can be displayed. The shape of the reflective or absorbent area can also contain nonlinearities z. B. could be present in the photosensitive arrangement, be compensated. In addition, the measuring probe of the invention can be statically calibrated so that it is always comparable Delivers results.

In the following the invention will be explained with reference to one shown in FIGS AusfUhrungsbeispiels described and explained in their mode of operation. Put it FIG. 1 shows an embodiment of the optical measuring probe, FIG. la an enlarged Representation of the right part of Fig. 1, Fig. 2 and 3 application example for the Measuring probe from FIG. 1, the measuring probe shown in FIG. 1 consists of two bundles 1 and 2 of individual light guides l / l, .. n and 2 / l ... n, which preferably go through the Fibers of a known fiber optic are formed. The bundle 1 lies with its end h on a light source 3 and leads its light to end a, that is brought to the measuring point. The bundle 2 leads to the measuring point, so at its end a recorded reflected radiation to a photodiode 4, which immediately is arranged at the end b of the bundle 2. The fibers are 1 / l ... n and 2 / l ... n both bundles 1 and 2 at end a so out; that - arranged linearly - each a fiber from bundle 1 is located next to a fiber from bundle 2. This arrangement is shown enlarged in Fig, la.

The respective measurement object is illuminated via the fibers 1 / l .., n while the fibers 2 / l ... n feed the light reflected from the measuring object to the photodiode 4. The photodiode 1S supplies a short-circuit current which is linearly dependent on the strength of the it depends on falling reflected light. Since according to Fig. La the fibers 1 / l .., n and 2 / i ... n of both bundles 1 and 2 at end a evenly over the entire measuring point are distributed corresponds to that supplied by the photodiode 4 at any point in time Short-circuit current immediately of the expansion of the at this point in time in front of the measuring point located reflective area.

So if the object to be measured does not have parallel; but, for example, on each other converging boundary edges rise or fall, the removable edge on the photodiode 4 Current during a movement of the measurement object to the same extent as the reflecting one Area at the measuring point changes. In general, one cannot do any with the objects to be measured presuppose a certain form; therefore, the measured object is covered with a reflective Provide an area that has a shape that is particularly suitable for recording measured values, This is described with reference to the application examples shown in FIGS.

In Fig. 2 is a key lever 5 with a projection 5a as the object to be measured shown, which moves up and down in the direction of rope, around the sequence of this To capture movement is that Approach 5a with a triangle 6 white paint or glued on white paper. Opposite him is the measuring probe with its end a, as indicated by dashed lines, brought.

The key lever is in its (upper) rest position. In this position, no light reaches the photodiode 4 and is generated there accordingly no electricity either. When the key lever 5 is depressed, its approach moves 5a with the triangle 6 downwards, and to the same extent as the reflective area increases in front of the measuring point, the current supplied by the photodiode 4 also increases.

If the movement proceeded steadily, this current would increase linearly on, in the case of irregularities in the sequence of movements, these are directly from the deviations of the photodiode current can be recognized by a linear increase. On a connected The oscilloscope, which shows the current flow, makes the movement sequence direct read off. If the lever 5 with approach 5a not by hand, but via a magnet o. Ä. Is moved, the course of the drive current can be oscillographic at the same time map and thus get an assignment of drive and movement.

When the button lever 5 is released, the projection 5a moves again up. The base of the triangle 6 appears first and then a continuously decreasing area at measuring point a, which represents a correspondingly decreasing current by the photodiode 4 results. Vibrations and the like are also shaped here of the key lever 5 directly in deviations of the photodiode current from a linear falling curve.

If, as indicated in Fig. 3, the movement of a rotating Measurement object 7 is to be recorded, a reflective area is used instead of a triangle 8 of the shape of a curved around an imaginary concentric center line 9 Triangle mounted on the measurement object 7 to get the same results as in the previous example.

The shape of the reflective area is light in other cases as well adapt to the application. Should a linear function, for example the distance-time function, the reflecting area is simply given the shape that a linear increase or decrease in the photodiode current with uniform movement would result. In this way, non-linearities can also be found in the characteristic of the photodiode 4 by corresponding edge curvature of the reflective area Balance 6 or 8.

In some cases I don't like the way; but the speed or The acceleration of the moving part 5 or 7 is also of interest. Both details can be derived mathematically or electrically from the distance-time function and can in the latter case be displayed directly on the oscillograph.

Instead of a triangle 6 in FIG. 2 or a curved triangle 8 In Fig. 3, a white line in or attach perpendicular to the direction of movement. In the first case, the end a is the Probe as shown, -in the second perpendicular to it opposite the measurement object 5 or 7 to be attached. In addition, the adjacent or one below the other arranged fibers l / l., n of the bundle 1 or those arranged accordingly Fibers 2 / l ... n of the bundle 2 Different amounts of light for each unit area Or lead away from the measuring point, z. B. from left to right or from increasing amounts of light from top to bottom, which is indicated by a rising in this direction Number of fibers per unit area is achieved. Then the same ore each other Effects as described above.

If the part to be examined 5 or 7 is very small and one accordingly requires a small reflective area 6 or 8 or a very fine line, a lens (not shown) can be arranged in front of it, which the triangle 6 (8) or a line provided in its place enlarged on the end of the bundle a maps. Without such a lens, movements of a few millimeters are possible Can still be evaluated very well in practice, with additional lenses one gets around a few orders of magnitude lower - The described arrangement can be statically calibrated, either with full reflection by setting the then accordingly obtained maximum value of the current supplied by the photodiode 4 or one therefrom recovered voltage or vice versa with minimal reflection. To check the Of course, any number of intermediate values can also be static in linearity check by using the assigned output voltage for a defined path is checked for proportionality. This calibration then also applies to the dynamic one Case. In this way, comparable results with high accuracy are always achieved.

Claims (6)

Expectations 9 optical measuring probe for dynamic distance measurement of moving parts with a light source and a light-sensitive arrangement as well as a plurality of light guides, characterized in that the light guides (l / l ... n, 2 / 1..0n) are combined into two bundles (1, 2), one of which (1) to the light source (3) and the other (2) leads to the light-sensitive arrangement (4), and to the Measuring point one light guide each (1 / l ... n) from the first bundle (next to one light guide (2 / l ... n) from the second bundle (2) is arranged linearly. 2. Measuring probe according to claim 1, characterized in that the to be measured moving part (5 in Fig. 2, -7 in Fig.: 3) at the measuring point with a defined Area (6 - in - Fig, 2, 8 - in Fig. 3) different from its surroundings Reflectivity or absorption capacity is provided. 3. Measuring probe according to Claim 2, characterized in that the area different reflectivity or absorption capacity (6 or 8) accordingly the function to be measured is formed, that is, z. B. to accommodate a linear Function triangular (6 in Fig. 2) to accommodate an angle in the form of a geometric one Figure of increasing width with the angle (8 in Fig. 3) and for receiving a quadratic or other nonlinear function with corresponding nonlinear Boundary lines. 4. Measuring probe according to claim 2, characterized in that the area different: reflectance or absorption capacity (6 or 8) rectangular is trained and the light guides of one or the other bundle (1, 2) are arranged in such a way that the through the conductors (1 / I ... n) of the first bundle (1) lighting led to the measuring point or through the conductors (2/1 ... n) of the second bundle - (2) for -light-sensitive arrangement (4) guided reflected Light in the direction of movement is to be measured part (5 or 7) according to the measuring functions increases or decreases. 5. Measuring probe according to claim 1 to claim 4, characterized in that that as a light guide (1/1 ... n, 2 / l ... n) -the fibers of a known fiber optic are used. 6. Measuring probe according to claim 1 to claim 5, characterized in - characterized that an'der measuring point between the part to be measured (5 or 7) and the common At the end of both bundles (1, 2) optical means are provided that support the part to be measured (5 or 7) or the area located thereon with different reflection or Map absorption capacity (6 or 8) on the common end of both bundles' (1, 2). L e r s e i t e