DE3143270A1 - Method for contactless measurement of the length of moved objects - Google Patents

Abstract

A method is described for the contactless measurement of the length (L) of moving objects with the aid of optoelectric sensors which are arranged at a distance from one another which has a specific length unit. For this purpose, an approximate value (LO) of the length of the object is firstly determined in a way known per se by determining the number of sensors (2 to 6) covered by the object (1) once the beginning (11) of the object (1) has reached a starting sensor (2). The residual length (L1 = L-LO) is then determined with the aid of time measurements (T1, T2) from the relationship <IMAGE> T1 signifying the time between reaching the beginning (11) of the object (1) in the case of a starting sensor (2) and reaching the end (12) of the object (1) in the case of the last sensor (4) still covered in the direction of movement, T2 the time between reaching the end (12) of the object (1) at this sensor (4) and reaching the beginning (11) of the object (1) at a reference sensor (7), and L2 the distance between the starting sensor (2) and the reference sensor (7). <IMAGE>

Description

METHOD FOR CONTACTLESS MEASUREMENT OF

LOCATION OF MOVING OBJECTS The invention relates to a Method for non-contact measurement of the length of moving objects with the help of of sensors, which are arranged from each other at a distance of a certain length unit are, and in which an approximate value ILO of the length of the object is thereby determined is that when reaching the beginning of the object at a start sensor the Number of sensors covered by the object is determined.

Such a method is described, for example, in GB-PS 1,542,286 described. In this patent it is proposed that to determine the Remaining length L-LO the object passed a second group of sensors whose distance is a fraction of the unit of length mentioned above. One Such a known arrangement is relatively complex, since a large number of sensors is necessary if the length determination with sufficient accuracy should take place.

From DE-OS 23 31 545 a method for determining the Length of staple fibers known. A first period of time is measured, which is a Fiber end needed to join two of the spaced apart at a known distance Move detectors past.

The speed is then derived from this time value the Fiber determined by dividing the distance by the first time period. the end a second amount of time it takes the opposite ends of the fiber to to move past one of the detectors, the length of the fiber is determined, by multiplying the speed by this second period of time. Particularly The disadvantage of this method is that changes in the speed of the fiber Can strongly influence the accuracy of the measurement.

The present invention was therefore based on the object of a method of the type mentioned above so that the number of required Sensors can be kept low despite increasing the measurement accuracy. aside from that speed changes of the objects should have as little influence as possible on the accuracy of the length measurement.

According to the invention, this object is achieved by the characterizing part of the claim solved.

Further advantages and details of the invention are set out below described on the basis of exemplary embodiments with the aid of figures.

It shows: FIG. 1 an object to be measured in its starting position for measurement; Fig. 2 the position of the object during the first time measurement, and FIG. 3 shows the position of the object during the second time measurement.

In FIG. 1, 1 denotes the object whose length L is determined shall be. For example, this item can be an over a roller table handle moving pipe (the roller table has been omitted for reasons of clarity).

The object has the beginning 11 and the end 12 and moves past sensors 2 to 7 in the direction of the arrow marked 13. Both Sensors are advantageously light barriers known per se. Each of the sensors contains a light source and a photocell. The item 1 acts as a reflector, so that light always gets into the photocells when the object moves past them.

The sensors 2 to 7 are connected to an electronic one via lines 21 to 26 Control and receiving unit 14, which contains a computer 141, connected. In the The length of the object determined by this unit is displayed in a display unit 15 shown.

As can be seen from Figure 1, the beginning 11 of the object 1 has just reached sensor 2 used as the start sensor. The sensors 3 and 4 emit corresponding signals to the unit 14 via the lines 22 and 23 and thus indicate that the object 1 is above them. The unit 14 can thus determine the approximate length LO.

To determine the remaining length L1 = L-LO, the time T1 is measured, that between reaching the beginning 11 of the object 1 at the start sensor 2 and the reaching of the end 12 of the object 1 at the sensor 4 passes (FIG. 2). This measurement can take place, for example, in that a contained in the unit 14 Counter (not shown) is started when the start sensor 2 arrives of the item 1 determined. The counter is then stopped again at the moment in which the sensor 4 detects the end of the object (the corresponding photocell no longer receives light).

With T1 = v where v is the speed of the object, the result is L1 = v x T1 (1) If one measures now, for example, with a second counter (also not shown) the time T2 that elapses between the reaching of the end 12 of the object 1 at the sensor 4 (start of the 2nd counter) and when it is reached of the beginning 11 of the object 1 a reference sensor 7 (stop of the second counter) passes (Fig.3), then from the relationship T2 = (L2-L1) v the speed v = (L2-L1) (2) T2 can be determined, with L2 being the distance between the start and the reference sensor.

Inserting equation 2 into equation 1 and solving that equation after 111, the remaining length is: T1 L1 = L2 x T1 (3) T1 + T2 The solution this equation is carried out, for example, with the aid of that designated by 141 in FIG Calculator.

The invention described above has been particularly useful in proven to measure the length of ears, but it can also be used in conjunction with other Objects such as sheet metal or rods are used.

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Claims (2)

Claim: Method for contactless measurement of length, Lvon moving objects with the help of sensors that are spaced from each other at a certain distance Unit of length are arranged and at which an approximate value 10 of the length L of the object is determined by the fact that when you reach the beginning of the object on one Start sensor the number of sensors covered by the object is determined, d a d u r c h e k e n n - that to determine the remaining length L1 = L - LOZ first the time, T1, is measured, which elapses between reaching the beginning (11) of the object (1) at the start sensor (2) and reaching the end (12) of the object (1) for the last sensor in the direction of movement that is still covered by object (1) (4) passes; - That then the time, T2, is measured between the reaching of the end (12) of the object (1) at this sensor (4) and the reaching of the beginning (11) of the object (1) passes a reference sensor (7), the reference sensor (7) in the direction of movement of the object after the start sensor (2) is arranged and is at a fixed distance, L2, therefrom; and - the remaining length, L1, then from the relationship Ti L1 = L2 x Ti + T2 is determined, and - that the such Determined remaining length, L1, to which the approximate value, LO, is added. 2. The method according to claim 1, d a d u r c h g e k e n n -z e i c h Not that light barriers are used as sensors (2 to 7).