DE1809990A1 - Method and device for measuring a dimension of a body by means of light indicators - Google Patents

Description

Method and device for measuring a dimension of a body by means of light indicators The present invention relates to a method for measuring one dimension one; Body in which a body is affected by a light ray field The light source is guided into a measuring field provided with light indicators falling shadow of the body is measured. The invention also includes one Device for carrying out the procedure.

For example, the saw blades of gang saws are in a sawmill adjusted to the thickness of the logs to be sawed.

Each frame saw is assigned a very specific scope class. When sawing, each trunk should be of the correct type, adjusted to the appropriate trunk thickness Frame saw are fed. For this purpose, the trunk thickness is measured beforehand, and the trunk is classified into the relevant circumference class on the basis of the measurement result. The measurement is carried out in such a way that the position of the two is determined by light rays diametrically opposite edges of the trunk in a) measuring field is determined. The distance between the two measured Corresponds to positions in the measuring field the thickness of the tribe.

Known measuring devices for this are based on the principle of de photocell pairs built, with a separate light transmitter and a separate light indicator for each light indicator Receiver are used and the measuring field au. numerous such light indicators is composed. Other known measuring devices are based on the principle of Light receiver and transmitter set up. With these the measuring field is with many Light transmitters provided at the same distance from each other, which are individually during a measurement light up one after the other. A pulse train generated in this way is displayed with a single light indicator read.

A notable disadvantage of these devices is that the body to be measured when measuring in such a position in relation to the measuring field found that not every position of the opposite body edges to be measured is accurate falls on a measuring point, but between two measuring points. This is the maximum error of the measurement result is equal to the size of two graduation distances for the measurement points. Around To reduce the size of the error, the pitch must therefore be reduced. this requires a larger number of measuring points and makes the equipment considerably more expensive. When using the last-mentioned principle, an angle error also arises if the position of the body between the light transmitter and light indicators is changed.

Furthermore, a measuring arrangement is known in which the rod-shaped body be moved past in their longitudinal direction along a measuring field. When the front end of the body has reached a certain fixed measuring point in the measuring field, is at the same time read the position of the rear end to a movable measuring head. That falls rear end of the body in the measuring range of the measuring head, its Size corresponds to the tolerance range of the body, the body is assumed; falls the rear end does not enter the measurement area, the body is excreted because its Length either exceeds or falls below the permitted tolerance range. These The arrangement assumes that the nominal length of the bodies is the same. The distance between the fixed measuring points and the measuring head is set before the measurement so that that it corresponds to the nominal length. With this arrangement, no body can measured whose nominal dimension is unknown. Also, measurements are at those bodies with randomly varied dimensions one after the other to the measuring field are impossible with this arrangement.

The present invention is based on the above-mentioned object Eliminate disadvantages. The method according to the invention stands out for the solution the task consists in that the body to be mesnonde enters the light beam field is led that one side of the shadow caused by the body @ r into a section of the measuring field, in which the light indicators in relatively close distances @ are arranged, and the other side of the shadow @ in a section de. Measuring f @ lde @ falls, in which light indicators are only present at further intervals, and that there. Lichtatrahlenfeld with regard to the measurement field during the measurement so back and forth it is pushed that the last-mentioned side of the shadow is exactly in front of a light indicator in the section of the measuring field with light indicators arranged at further intervals falls.

With the method according to the invention, a measurement accuracy is achieved which corresponds to the pitch of the denser sections. So by being close to one another Light indicators can only be used in part of the measuring field, while for the larger part of the measuring field light indicators at further intervals suffice without impairing the measurement accuracy, a significantc Number of light indicators and the associated equipment saved. Through the outward and pushing the light beam while measuring ensures that the position of the Body edge (shadow)? those measured in the further divided section of the measuring field will always fall exactly on a measuring point in this further divided section can. When the beam of light is shifted back and forth, I also move the shadow of the body: on the measuring field, and this gives the minimum measured value in the Moment at which the shadow falls on a measuring point in the further divided section falls. The electronic device required to select the minimum reading is known per se. Because the width of the light cone emitted by the light source corresponds to the most frequently measured dimension, I reduce the angle error, the depends on the position of the body between the transmitter and the light indicator.

The invention is described below with reference to the accompanying Drawings explained in more detail. It show: Pig. 1 an embodiment of an inventive Device for measuring the thickness of a trunk schematically in a plan view, Ftg. 2 shows an arrangement for the periodic shifting of the light beam field, schematically in a side view and FIG. 3 shows a cover disk of the arrangement according to FIG. 2 of front.

In Fig. 1, 1 denotes a V-shaped fixed frame, the two legs of which are each provided with a measuring field 2 formed from light indicators are. A conveyor 3 guides a log A, the thickness of which is measured in inches, at right angles to the frame past the measuring field. A light source 5 is assigned to each measuring field, a light beam field 6 essentially at right angles to the relevant measuring field sends.

Each measuring field 2 is divided into two sections, namely a first Section A, in which the light indicators gates 7 at closer pitch, z. B. about 3.2 mm (1A inch), and a second section B in which the Light indicators 8 in further pitch, z. B.

2.54 cm (1 inch) are arranged. The light source 5, the conveyor 3 and the measuring field 2 are coordinated so that one 3 side 6 'of the dated The trunk of the cast shadow falls into the denser section A of the measuring field and the other side 6 in the further divided section B. Since the tribes are always are on the conveyor 3, their lower edges also rest in each case almost the same place, and the denser section i; t roughly in proportion arranged to do so.

In addition, the light beam field is arranged so that it is at Measure back and forth. According to Fig. 2 and 9, this is done by attaching a rotating Cover disk 9 with an eccentric hole 10 in front of the light source 5 is achieved.

When the cover disk rotates, the light beam field shifts through the hole 10, and the shadow cast by the trunk oscillates as a result the measuring field back and forth.

The size of the pendulum must be at least one pitch of the further divided section.

In the case shown in Fig. 1, the measurement takes place from two directions, and the measuring fields are read alternately. The trunk thickness is measured through the shadow on the measuring field by placing the light indicators in the further divided Section B multi-word in relation to the dense section A can be read. At the end of the game, in the specified case, the light indicators 8 in section B several Impulse against an impulse of the light indicators 7 in section A.

Reading takes place either when the shadow is on a light indicator in the section that is further divided, it happens continuously, wobci the minimum result is chosen from the results. The reading frequency should be significantly greater than the frequency of movement of the shadow.

The drawing and the corresponding part of the description are only for this purpose intended to illustrate the basic idea behind the invention. The idea of the invention can also refer to bodies other than stems and for the determination of other dimen @ ions al the thickness can be applied. - The shift of the light beam field can, for. B. also by a vibrating light source or by shifting the one to be measured Body: or of the measuring field in relation to the light source or only in relation to each other.

The in the above description, in the drawing and in the following patent claimsCrnn disclosed feature of the; Registration @ object can be used individually or in any combination for the Realization of the invention in its various embodiments is essential be.

Claims (5)

P a t e n t a n ;; check 1. Method of measuring the dimension of a body in which a body is guided through a light beam field of a light source and one on one with light indicators The measuring field of falling shadows of the body is measured, characterized in that that the body to be measured (4) is guided into the light beam field (6) that one side (G ') of the shadow caused by the body into a section (A) the measuring field (2) falls in which the light indicators (7) are relatively dense Spaced, and the other side (G ") of the shadow in one section (B) of the measuring field falls, in which light indicators (8) are only present at further intervals are and that the Lichtstrehlenfeld (6) with respect to the measuring field (2) during the Measurement is moved back and forth so that the latter side (6 ") of the shadow exactly in front of a light indicator (8) in the section (B) of the measuring field with further Light indicators arranged at intervals. 2. The method according to claim 1, characterized in that the light beam field (6) is moved to the fixed measuring field (2). 3. Apparatus for performing the method according to claim 1, the a light source (5) for generating a light beam field (6), means of transport (3) for guiding the body to be measured (4) through the light beam field, one with Light indicators (7, 3) provided measuring field (2) because the caused by the body Shadow falls, as well as means of measuring of the falling on the measuring field Shadow, characterized in that the measuring field (2) has a first section (A) with several fixed light indicators (7) closer to each other and a second section (B) with several fixed light indicators (8) in further Distances to each other includes and that means for achieving a back and forth relative movement between the light beam field (6) and the measuring field (2) Measure is provided. 4. Apparatus according to claim 3 with an electrical measuring device for measuring the light beam field falling on the measuring field by means of light indicators emitted pulses, characterized in that the ratio between the the light indicators (8) in the section (B) of the measuring field with at further intervals arranged light indicators and the pulses emitted by light indicators (7) in section (A) of the measuring field with light indicators arranged at closer intervals emitted pulses is chosen to be equal to the ratio of the distances between the light indicators both section (A, B) of the measuring field (2). 5. Apparatus according to claim 3, characterized in that a device to move the light beam field (6) with respect to the fixed measuring field is provided.