DE202007018457U1 - Measuring device for measuring a property of a mat and / or plate - Google Patents

Abstract

contraption to carry out a method for measuring a property of a mat (11) and / or Plate taken along a conveyor line is eligible, with several each transmitting a measuring signal transmitters and with a plurality of each a measuring signal value detecting receiver, the pairwise associated with each other, and the transmitter-receiver pairs (16, 17, 18, 19) on both sides on opposite sides of the conveyor line are arranged, characterized in that the transmitter and the receiver from a measuring position in which the respective transmitter-receiver pairs (16, 17, 18, 19) are aligned facing each other, in a calibration position are movable, in which the transmitter or the receiver of a transmitter-receiver pair (16, 17, 18, 19) a receiver or a transmitter of another transmitter-receiver pair (16, 17, 18, 19) is facing.

Description

The The invention relates to a device for carrying out a method for Measuring a property of a mat and / or a plate along a conveyor line pumpable is, in which several each one measuring signal emitting transmitter and several each receiving a measured signal value receivers paired with each other and the transmitter-receiver pairs on both sides at opposite sides Pages of the mat and / or plate are arranged.

A Such device are used in the manufacture of wood-based panels for example, to determine the basis weight and / or the material thickness used. In the production of wood-based panels from chips and / or Fibers will be one as possible uniform basis weight of sought for plates to be produced. To achieve this, will be first corresponding fiber mats having previously sized chips and / or fibers, through one as possible uniform dispersion the chips and / or fibers prepared. These fiber mats are subsequently in a suitable press to the plates to be produced usually at higher Temperatures pressed together. The mats for making the fiber used machines usually have Adjustment on, with which the scattering of the chips and / or Fibers can be influenced.

to Control and control of the dispersion of the chips and / or fibers are usually basis weight measuring systems used as the distribution of the basis weight of the fiber mat equal to the basis weight distribution before pressing produced plate is and is not changed by the pressing process. By the pressing process, the basis weight only a total for fleeting Components of the material as well as to reduce moisture, not but the distribution in the longitudinal and transverse directions modified for production.

The Basis weight measuring systems often have an X-ray source and one on the opposite Side of the material flow detector or radiation receiver, the for the detection of X-rays suitable is. The chips or fiber material penetrating X-ray radiation is dependent the amount of material more or less weakened. From the weakening of the X-rays can the basis weight be determined at the respective location.

The used X-ray sources or alternatively used isotope emitters send a relative constant measuring signal off. The detectors, however, do not show this constancy, so that despite the constant measurement signal itself the acquired measurement signal values over time with an ever-increasing Move error. Therefore, it is necessary that at regular intervals said bright measurement performed becomes. With Hellmessung a measurement is called, in which the Measuring signal of the transmitter is detected directly by the receiver, without it through a material to be checked penetrated, that is, that there is no mat or plate in the measuring section.

It It is known to use this calibrating measurement in the gaps in the light Material flow between isolated mats and / or plates perform. This but is only possible if the gaps have a sufficient size. With increasing conveying speed or even with a continuous strand in the production line this is at least much more difficult, if not impossible. Nevertheless, a bright measurement carry out to be able to It is known that the transmitter and the detector are movable in a measuring device provided so that they led out of the range of material flow or swung out be carried out and off the same carrying out the bright measurement. The one for this necessary constructions must but very precise his and their production is therefore complicated and expensive. Further require the pivotable measuring devices significantly increased space requirements.

In front In this context, it is the object of the present invention a calibration for one To allow measurement of a material property in a simple manner.

These The object is achieved by a device having the features of the claim 1 solved.

at the device is inventively provided that the transmitter and the recipients from a measurement position in which the respective transmitter-receiver pairs aligned facing each other, in a calibration position be moved, in which the transmitter or the receiver of a transmitter-receiver pair a receiver or a transmitter of another transmitter-receiver pair are facing.

The essential essence of the invention is that the pairwise assignment of transmitter and receiver for the actual measurement of the material properties is maintained, but aligned for a calibration the transmitter and / or the receiver in a calibration position on a receiver or a transmitter of another sensor pair become. The pairing made for the measurement is temporarily canceled according to the invention for the calibration. For the calibration It is irrelevant to the detectors whether the measurement signal for the bright measurement is transmitted by the associated transmitter partner or another substantially comparable transmitter of another sensor-receiver pair.

Prefers become the transmitter-receiver pairs provided such that on both sides of the mat and / or plate respectively Transmitter and receiver different Transmitter-receiver pairs be arranged adjacent to each other. This leads to a bilateral of conveyor line each alternating arrangement of the transmitter and receiver.

In Advantageously, the transmitter and the receiver are rotatable intended. The rotation is a simple change in position from measuring position to calibration position.

Prefers becomes the measuring direction of the associated transmitter-receiver pairs in the measuring position orthogonal to the surface of the mat and / or plate aligned. Furthermore, the measuring direction is preferred in the calibration position parallel to the surface the mat and / or plate aligned.

In Advantageously, it is provided that for measuring X-ray radiation is used. Alternatively, isotope radiation is used for the measurement, on the one hand monochromatic and on the other higher energy radiation properties having. As an alternative, ultrasound is used for the measurement.

following The invention will be described with reference to a detailed description of a embodiment with reference to the attached Drawings closer explains in which:

1 shows a perspective view of a known measuring device,

2 shows a perspective view of a measuring device according to the invention,

3 the measuring device according to the invention 2 in a front view shows

4 the measuring device off 3 with swung into the calibration position transmitters and receivers and

5 the measuring device off 3 in which transmitter-receiver pairs are partially in measurement position to part in calibration position.

In the 1 schematically shows a known device for basis weight measurement as a part of a production line for the production of wood-based panels, such as chipboard and / or fiberboard shown. Although this measuring system is presented herein as a device for the wood-based panel industry, it is clear that also plate-like products made of other non-woody material can be examined for their basis weight using the apparatus according to the invention.

After a mat 1 in the 1 is indicated by means of a dashed line, provided by scattering of chips and / or fibers, it is continued in a production line along a conveying path and conveyed by the measuring device according to the invention. In the further course of the production line, the mat 1 in a suitable pressing device (not shown) pressed to the plate to be produced. The term conveyor line refers to the volume area of the production line that the spread mats 1 singly or as a continuous strand. The spreader itself is not shown in the figure.

The measuring system shown has a frame 2 with two substantially vertically oriented and arranged laterally next to the conveyor section supports 3a and 3b on. The pillars 3a and 3b are by two frame girders 4a and 4b connected with each other. Here is the first frame support 4a above and the second frame girder 4b below the conveyor line with the mat 1 intended. The conveying direction of the conveyor line or the plate 1 will be in the 1 with the help of the arrow 5 displayed.

The measuring system shown has several transmitter-receiver pairs 6 . 7 . 8th and 9 on each of which all transmitters on the lower frame support 4b are arranged. All receivers, on the other hand, are on the upper frame carrier 4a arranged. The transmitter-receiver pairs 6 to 9 are each facing each other on the corresponding frame members 4a respectively. 4b next to each other and across with respect to the conveying direction (arrow 5 ) attached.

In the 2 a measuring device according to the invention is shown schematically sketched, which is a frame 12 with two substantially vertically oriented and arranged laterally next to the conveyor section supports 13a and 13b having. The pillars 13a and 13b are by two substantially horizontally oriented and arranged parallel to each other frame support 14a and 14b connected. Here is the first frame support 14a above and the second frame girder 14b below the conveyor line with a mat 11 provided so that the conveyor line through by the two side supports 13a and 13b and the two frame members 14a and 14b defined surface passes substantially orthogonal to this. The Conveying direction of the conveyor line or the plate 11 will be in the 2 with the help of the arrow 15 displayed.

The measuring system shown has several transmitter-receiver pairs 16 . 17 . 18 and 19 on each of which all transmitters on the lower frame support 4b are arranged. All receivers, on the other hand, are on the upper frame carrier 4a arranged. The transmitter-receiver pairs 6 to 9 are each facing each other on the corresponding frame members 4a respectively. 4b next to each other and across with respect to the conveying direction (arrow 5 ) attached.

In the 1 the transmitters are shown only sketched schematically and they can be designed both as an X-ray source and as an isotope radiator. Furthermore, the receivers are also sketched only schematically, and evaluation devices for the respective measured signal value, for example a suitable microprocessor, can be integrated directly in the respective housing of the receiver, in order to allow the most compact possible construction of the entire measuring system. To better distinguish the transmitter and receiver from each other they are shown differently in the figures.

In the 2 It can be clearly seen that according to the invention on each frame carrier 4a and 4b in each case the transmitter and receiver are arranged alternately, ie the transmitters is at least one receiver adjacent and no transmitter is provided directly adjacent to another transmitter. Although in the figure exactly four transceiver pairs 16 . 17 . 18 and 19 it is clear that the number of transmitter-receiver pairs can be any number n ≥ 2.

In the 3 to 5 is the measuring system of the 2 reproduced in a front view. Here corresponds to the in the 3 illustrated situation of those from the 2 ie all transmitter-receiver pairs are in their measurement position and the transmitters and the receivers are each oriented to their associated partner. The radiated by the broadcasters and the mat 11 penetrating measuring signals are through the lines 20 in the 2 indicated, so that the assignment of the respective transmitter-receiver pairs 16 . 17 . 18 , and 19 is clearly recognizable.

In the 4 The transmitters and receivers are each rotated 90 °, and each transmitter is aligned with a receiver of another transmitter-receiver pair. In the calibration situation shown for performing a bright measurement, that on the lower frame support 14b arranged transmitter of the transmitter-receiver pair 16 now on the same frame girder 14b arranged receiver of the adjacent transmitter-receiver pair 17 facing. At the same time is the transmitter of the transmitter-receiver pair 17 to the receiver of the transmitter-receiver pair 16 aligned.

In the same way, the respective assignment of the transmitter-receiver pairs 18 and 19 repealed, leaving the transmitter and the receiver of the transmitter-receiver pair 18 each to the receiver and transmitter of the transmitter-receiver pair 19 are facing. The emitted rays for the light measurement are through the lines 21 in the 4 indicated and it can be seen that the measuring direction parallel to the surfaces of the non-irradiated mat 11 is provided.

Finally, based on the 5 a situation in which at the same time a measurement of the material property and a calibration are performed. The transmitter-receiver pairs 16 and 19 are here facing each other and perform the actual measurement. The emitted measuring beams are through the lines 20 in the 5 indicated and penetrate the mat 11 , Furthermore, the associated pairing is the transceiver pair 17 and 18 canceled, leaving the transmitter of the transmitter-receiver pair 17 with the receiver of the transmitter-receiver pair 18 performs a bright measurement. The calibration signals that the mat 11 do not penetrate, are in the 5 through the lines 21 indicated.

In order to be able to take account of any deviations in the measurement signal qualities of the transmitters that occur, several light measurements are carried out before the production line is put into operation. First, the respective measurement signal values for a bright measurement of the associated transmitter-receiver pairs 17 to 19 recorded and filed. Subsequently, corresponding light measurements with the possible calibration partners of the respective receivers of the transmitter-receiver pairs 17 to 19 , ie with the transmitters of the respective adjacent transmitter-receiver pairs. These measured signal values recorded in this way are also stored. The plurality of measured signal values can now be compared with one another and the ratios stored during production from the measured signal value of a bright measurement with a calibration partner and the cached conditions an exact calibration for the measurement of the respective associated transmitter-receiver pairs 17 to 19 perform.

Although in the foregoing description the invention is based on the measurement of a mat 11 From chips and / or fibers has been explained, it is clear that the inventive arrangement of the transmitter-receiver pairs 16 to 19 can also be used in a measuring device for measuring an already finished pressed plate. Because the calibration or the light measurement respectively takes place on one side of the conveyor for the mat / plate, the invention can also be used in production lines with endless strands. The calibration can be carried out at cyclic intervals in order to be able to promptly compensate for and compensate any changes in environmental conditions.

Claims (11)

Device for carrying out a method for measuring a property of a mat ( 11 ) and / or plate, which is conveyable along a conveyor line, with a plurality of each transmitting a measuring signal transmitters and with a plurality of each measuring signal value detecting receiver, which are pairwise associated with each other, and the transmitter-receiver pairs ( 16 . 17 . 18 . 19 ) are arranged on both sides on opposite sides of the conveyor line, characterized in that the transmitter and the receiver from a measuring position in which the respective transmitter-receiver pairs ( 16 . 17 . 18 . 19 ) are oriented towards one another, are movable into a calibration position, in which the transmitter or the receiver of a transmitter-receiver pair ( 16 . 17 . 18 . 19 ) a receiver or a transmitter of another transmitter-receiver pair ( 16 . 17 . 18 . 19 ) is facing. Device according to claim 1, characterized in that the transmitter-receiver pairs ( 16 . 17 . 18 . 19 ) on a frame ( 12 ) are provided such that on both sides of the conveyor line each transmitter and receiver of different transmitter-receiver pairs ( 16 . 17 . 18 . 19 ) are arranged adjacent to each other. Device according to one of the preceding claims, characterized characterized in that the transmitter and the receiver are rotatably provided. Device according to one of the preceding claims, characterized in that it is arranged to carry out a method for measuring a property of a mat ( 11 ) and / or plate which can be conveyed along a conveying path, in which a plurality of transmitters each transmitting a measuring signal and a plurality of receivers respectively detecting a measuring signal value are assigned in pairs to one another and the transmitter-receiver pairs ( 16 . 17 . 18 . 19 ) on both sides on opposite sides of the mat ( 11 ) and / or plate, in which the transmitters and the receivers from a measuring position in which the respective transmitter-receiver pairs ( 16 . 17 . 18 . 19 ) are moved to face each other in a calibration position, in which the transmitter or the receiver of a transmitter-receiver pair ( 16 . 17 . 18 . 19 ) a receiver or a transmitter of another transmitter-receiver pair ( 16 . 17 . 18 . 19 ) is facing. Device according to one of the preceding claims, characterized in that it is arranged to carry out a method according to claim 4, characterized in that the transmitter-receiver pairs ( 16 . 17 . 18 . 19 ) are provided such that on both sides of the mat ( 11 ) and / or disk respectively transmitters and receivers of different transmitter-receiver pairs ( 16 . 17 . 18 . 19 ) are arranged adjacent to each other. Device according to one of the preceding claims, characterized characterized in that it is arranged to perform a Method in which the transmitter and the receiver are rotatably provided. Device according to one of the preceding claims, characterized in that it is arranged to carry out a method in which the measuring direction of the associated transmitter-receiver pairs ( 16 . 17 . 18 . 19 ) in the measuring position orthogonal to the surface of the mat ( 11 ) and / or plate is aligned. Device according to one of the preceding claims, characterized in that it is adapted to carry out a method in which the measuring direction in the calibration position parallel to the surface of the mat ( 11 ) and / or plate is aligned. Device according to one of the preceding claims, characterized characterized in that it is arranged to perform a Method in which X-ray radiation is used for the measurement. Device according to one of the preceding claims, characterized characterized in that it is arranged to perform a Method in which isotope radiation is used for the measurement. Device according to one of the preceding claims, characterized characterized in that it is arranged to perform a Method in which ultrasound is used for the measurement.