SE440405B - DEVICE FOR DETERMINING THE DIRECTION DISTRIBUTION OF FIBERS IN THE PLAN FOR A CLOTHING MATERIAL - Google Patents

Description

7901903-0 ladders, e.g. through the so-called zero-span method. As with those The above methods are this method time consuming ooh can only applied to taken test pieces, so check on a continuous path can hardly be done in practice. Optical methods based on laser technology have been used turnaround, so far to a limited extent, as shown by ref. 19-22.

The starting point for the invention has been the realization of a need to be able to control directional distribution during operation the fibers in the production of cloth-like materials.

The problem is largely the same, neither the presentation takes place in the form of laying a slurry on a wire or if the laying is done dry and the fibers are then joined together, such as is common in the manufacture of certain nonwovens.

Fundamental to the diffraction phenomena is that a structure, for example a grating, will scatter electromagnetic radiation with a larger angle, the finer the lattice structure is. A single fiber can, from the wavelength point of view of the radiation, be considered as long and will, if irradiated by an electromagnetic wave, scattering radiation perpendicular to its own direction, while in the longitudinal direction of the fiber essentially no radiation comes to spread. If a cloth-shaped material is irradiated, you will to have a pattern on the opposite side to the light source, which at least stone mainly consists of the sum of the dispersal contributions from all the irradiated fibers. If we then ignore the very smallest - the scattering angles, you will get in a detection plan a diffraction image, which provides information on the fiber statistics orientation distribution. Dm fiber distribution is completely random, you will get a completely symmetrical pattern, but if the distribution one is characterized by the fact that many more fibers lie in a certain direction (machine direction), then more radiation will be present in directions perpendicular to or near perpendicular thereto direction.

According to the invention, it is now possible to arrange an Liok equipment with a loser on one side of the examined material material and a detector on the other, the undiffracted one the radiation on the other hand forms an axis of symmetry, against which a detection plane is perpendicular. 7901905-0 A detection device specially invented for the purpose can now under Neglect of the intensity-dominant, undiffracted radiation thereferferently detect the scattered the radiation, in that the detection device reaches at least two different, light-sensitive areas, whereby the light is actuated simultaneously can be detected For two different directions of propagation, which inclined to the said axis of symmetry is rotationally shot.

Upp ¥ ingnings ¥ ördelten och properties, which will be explained in more detail in connection with a special embodiment, obtained by a device according to claim 1. Advantageous EXECUTION WORMS As stated in the subclaims.

A more detailed explanation will now be provided with point ¥ robbery an exhaustion example, illustrated by the Figures.

Fig. 1 shows a device with a laser on one side of a fiber material and one detector unit on the other. Fig. 2 shows an embodiment Form of a differential detector. Fig. 3 shows a block suhema over electronic circuits belonging to the device.

The example shown in Fig. 1 comprises a movable web 3 of a material to be examined on the invention the way. The web 3 runs over a sliding plate 2 and is towed in one machine not shown, which is usually the machine on which the web is work. On a paper machine, the device may, for example, be immediately before winding the finished track. A laser 1 emits a collimated and coherent light beam 12. It is important that the beam is a laser beam due to the outgoing the light is then well collimated, coherent and monochromatic. Then the beam passed the path 3, it comes along with due to scattering slightly deflected light to pass into a chamber 4 via a light filters 5. Due to the monochromatic laser light, can the filter's passband is kept very narrow, which has an effect of the room lighting becomes negligible. Preferably the tilt is one interference filter, in our case of model Ûriel U 572 (6328 Ångström).

For practical purposes, Before the Filter is an iris aperture (not shown).

At a distance of about 32 cm inside the ïíltret one thaws holder 5 accommodating a special photon detector 7 and an aperture 8 in the order now mentioned. Then the design of the Photon Detector is important the thawing, it will now be described in more detail in connection with iig. 2. 7901903-0 As shown in Fig. 2, the detector is a round disk with one through heel 11 in the middle, intended For the undisturbed part of the laser beam, so that it can pass through. The other part of the disk is divided into eight equal circle sectors 13.

The detector is basically a photocell of the barrier layer type. IN In principle, it consists of a semiconductor wafer, which on the one hand, the back according to the Figure, is provided with a conductive layer, and on the front with a transparent, conductive layer, which is divided into the mentioned sectors. Um light enters the translucent the conductive layer, an electrical voltage will be generated between the backsheet and the conductive, transparent layer.

As shown in Fig. 2, there are 7 wires in the detector device arranged to each of the sectors 13 of the conductive layer.

The sectors are of course isolated from each other. At this point the example is Four of the sectors are interconnected in pairs, while they others are not used. The two interconnected pairs of sectors are connected to their respective output lines designated MR resp. TMR (counter- corresponding machine direction resp. across the machine direction in the reversal being the EMBODIMENT).

The sector detector 7 has been specially manufactured to order For the purpose of Solar Systems Inc., 5124 Central Park Ave., Skokie, Illinois, USA.

As shown in Fig. 1, the unfractionated radiation continues. a 12 through the center hole 11 of the detector 7 through the aperture 5 and a surface additional aperture 9 to a conventional photodetector 10, which leaves a signal corresponding to the transmitted light fraction. Fig. 3 shows a block diagram of associated electronics and display devices. The photo streams From the outputs MR and TMR and From the detector 10 are each consumed on different dif- ferential amplifiers 31, 32, 33, of conventional integrated type. Direct outputs PCX, PCY and PCTRANS Available From these, which provide torque values for both the differential spread and for the path transmission Ability. The first two signals are routed to each its integrator circuit 34, 35, likewise of conventional type, added sample / hold circuits 37, 38 and controlled by a clock circuit 36. There are thus periodically taken averages For the diF- Fermentally occupied spreads. The ratio between these values calculated by an analog divider circuit 40. The For use here 7901903-0 circuit 8013 is so constructed that one signal must be attenuated with a clock 10, the dividing circuit 40 was at one input is Equipped with a damping circuit 39.

At the output of the analog divider, an output is obtained. signal, which is called the orientation index. Under the control of generator 36 is then passed the orientation index and the value of the mission to display devices.

The signals obtained can, in addition, for controlling purposes can also be used for control of e.g. the discharge rate in a paper machine.

In the example of desiccation shown, it has differential the detector a diameter of 50 mm. The laser is arranged some centi- meters below the moving path, and the distance between the the detector 7 and the path 3 are 449 mm. Hole 11 in the differential detection tower has a diameter of 5 mm, meaning that the detection angle is Hungarian 0.3-30. The number of sectors is 12, meaning that For each of it is detected within 300, calculated perpendicular to the laser beams. The interference filter is located approximately 318 mm Off diF ¥ erantald detector.

The detection device is completely housed in a longitudinal tube 60 cm and the diameter 15 cm.

Through the detection of the directly transmitted light, an opportunity is measured to measure the basis weight of the web, as the weakening is determined by the expression I / IÜ = e at where I is the intensity of the light attenuated by absorption, IG intensity without absorbent material, t basis weight and a one of the light wavelength and the material constantly dependent. The orientation index depends, as stated above, on the one of the fibers in the material. The spreading angle used is 0.3-30 has proved suitable For paper ¥ iber but can of course be customized to different materials. Very narrow tiers give greater dispersal angles, while coarser tiers give smaller scattering angles. For some applications, where the material also contains particles, scattering light, the detected scattering angles may be passes. so that sufficient selectivity is achieved in favor of the dispersal properties of the larvae, thereby reducing dispersal angles selected, where the spread of the fibers dominates. 7901903-0 References 15. 11+. 15. 16. 17. 18. 19. 20. 21. 22.

. Laníelsen, R. and Steenberg, 3 .: Kler-xrfr, P: Wocheiiblatt Papierfabrikation 69 (1958) 100.2, Swedish Pappertidn. 50 (1947) 501- Einger, E.R. and Majewski, Z.J .: Tappi 57 (1954) 216.

.Bergström, J., Brauns, O. and Svenson, Å .: Svensk Ieppers- tiä fl i fl å 5? (1954) 695- Andersson, O. and Bergström, J .: Thppi 37 (1954) 542.

Juflt, 11 .; Das Papier 12 (1958) 568.

Judt, M .: Das Papier 15 (1959) 46.

Glynn, P., Jones, H.W.H. and Gallay, W .: Pulp and Paper Mag. of Can. 60 (1959) T516.

Toroi, M .: Paperi ja Puu 41 (1959) 271.

Prusas, Z.C .: Tappi 46 (1965) 525. saick, A.M. = Sisson, W.A. (1955) 295- Clark, G.L .: Chemistry and Industry, January 18, 1969. and Clark, G.L .: Ind. Eng. Chem. Anal. Oath. 5 Terri 55 (1950) 584- Centola, G .: Das Papier 9 (1955) 588.

Friedlander, P.H .: Ihlp and Paper Mag. of Can. 59 (1958) 1, 102.

Ruck, H. and Krässig, H .: Pulp and Paper Mag. of Can. 59 (1958) 6, 185.

Kallmes, O.H .: Tappi 52 (1969) 482.

Goodman, J .W .: Introduction to Fourier Optics, San Francisco, 1968, pp. 77.

Stone, J .M .: Radiation and Optics, McGraw-Hill, San Francisco, 1962 pp. 107.

Gharrier, J .PL and Marchessault, R.H .: Fiber Science and computer science (5) (1972).

Rudström, L. and Sjölin, U .: Swedish Forest Iroducts Research Laboratory, Message 69, 1970.

Kornyukhina, T.A. and Borzunov, I.G .: Teklmologiya Textil noi Promyshlennosti 1976 111: 5 (pp. 19-22).

Mc GramßHill,

Claims (4)

7901903-0 P a t e n t k ria v Device for determining the directional distribution of fibers in the plane of a cloth-shaped material (5) made of discrete fibers, wherein a laser (1) is arranged to direct a laser beam substantially perpendicular to one side of the material and a light detector (7,10 ), coupled to the material, is mounted on the other side of the material and arranged to measure the circumferential angular distribution of the radiation scattered in the material substantially perpendicular to the laser beam, characterized in that the light detector for enabling simultaneous detection is divided into in an annular sector field (15) arranged around the transmitted and unspread laser beam, preferably occupying BO-45 ° of the circumference, which sector fields have separate outputs. Device according to claim 1, characterized in that the detector also has a center field (11,10) for detecting light transmitted without change of direction, which center field has a separate output. Device according to claim 1 or 2, whose detector is a photocell of the barrier layer type, with a conductive layer on the back side and a conductive, light-transmitting layer on the front side, characterized in that the layer on the front side is divided into spaced apart layers. insulated portions, to which electrical wires are connected, constituting the said, separate outputs. Device according to claim 2 or 5, characterized in that in relation to the center field, sector fields opposite in pairs have their outputs connected in parallel and connected to a calculation unit (40) arranged to calculate an orientation index, constituting the ratio between the intensities of radiation scattered in two perpendicular spreading planes