DE2104916A1 - Mesh monitor - using an optical system and reflector to control mesh quality by light impulses - Google Patents

Abstract

The loom-mounted light source is concd. on the mesh, passing to a reflector where, on the return path, a partial mirror is angled to divert the impules to a counter. The angle of the mirror, the speed of the mesh and a code disc give a pre-set value for the mesh quality desired, the counter giving a comparison with standard on the light impules generated by the mesh in terms of meshes per cm.

Description

Mesh size measuring device for sieve fabrics and the like In technical Woven fabrics made from plastic or metal threads used in papermaking the mesh size is an important determinant of the quality of the paper Size. So far, the mesh size is determined with the help of a magnifying glass and delimitation a certain length of fabric by counting the number of wefts - within the specified Route determined by visual inspection and by hand. As the thread thickness is known in each case there is a clear connection between mesh size and mesh number within a certain measuring length.

The invention is based on the object of determining the mesh size of screen fabrics or similar webs of fabric automatically, and objectively by a measuring device, to be determined contact-free as possible, even if the screen mesh is very fine-meshed. In addition, the measuring device should be conveniently built into the looms can be.

The solution to the problem was found in a measuring device, which is characterized in that by means of an optical beam path from the screen fabric a limited measuring area is illuminated and by means of its enlarged image the light and dark areas one after the other through a relative movement of a slit diaphragm made accessible to a radiation receiver and its light-dark reactions in one Counter can then be recorded, for example, for display, registration, signaling or regulation to be further processed.

The regulation can, for example, be used to adjust the mesh size during manufacture keep constant.

According to the further invention, the back (underside) of the fabric largely kept free of the measuring device.

For this purpose, the light source to the screen mesh is in the beam path a partially transparent e.g. semi-transparent mirror switched on and behind the Only a reflector is attached to the screen mesh, which the screen meshes through falling rays, which then move diagonally from the partially transparent beam to the beam path standing mirror and deflected sideways to the slit diaphragm.

As a result, the entire measuring device is practically on one side of the sieve fabric, whereby the installation in the loom or other manufacturing machine is very relieved.

If you make the partially transparent mirror movable, for example going back and forth, swinging or rotating, there is the possibility of the slit diaphragm and to arrange the radiation receiver in a fixed position, because that is rejected in the moving mirror Image of the measurement area can be moved optically over the slot so that the light and dark areas through the slit diaphragm corresponding impulses generate in the radiation receiver. This particularly advantageous embodiment of the Invention will be described in more detail with reference to the drawing.

You can also have a projection screen or another mirror opposite the slit diaphragm or the slit diaphragm preferably at the same time make movable with the radiation receiver in relation to the image.

If the measuring device is not built into a manufacturing machine, but only used as a test device, the partially transparent mirror can be omitted and the image of the measuring district e.g. on a transparent projection surface behind which the slit diaphragm and radiation receiver move.

The measuring area is expediently enlarged for pulse counting, in the case of coarser tissues, the magnification can be correspondingly lower, possibly completely omitted. The pulses from the radiation receiver are amplified in the usual way. The measuring device can work intermittently or continuously. After the further Invention is with the movement device for the level, the projection surface or the slit diaphragm also connected to an automatic shutdown, which the Movement or the counting process stops after each scanning of the image or causes a mark.

The new mesh size measuring device provides a reliable one and correct information about the respective mesh size even with very fine meshes Tissues and is independent of subjective counting errors. The measurement can also be significant can be done faster. It can be registered automatically, also on remotely transmitted to a central control station and for signaling if the deviation is too great the mesh size of the target value. When installing in a manufacturing machine, for example in a loom or the like, a control process for correction can also be used are brought about automatically in the event of deviations from the setpoint. The measuring device can be built very compact and on one side to the fabric web in the machine install more efficient use of space.

The tissue is neither damaged nor touched. Anyone can do it Kind of rays, including invisible rays, are used.

In the drawing is a particularly advantageous embodiment of the invention shown in the scheme.

A projection incandescent lamp 1 illuminates the condenser 2, which is a Image of the lamp filament in the imaging optics 5 designs. The light beam passes through in this way the partially transparent inclined mirror 4.

An image of the aperture 3 is created on the fabric sheet. The aperture is designed so that your image on the fabric sheet is equal to or larger than the one to be displayed Measuring district 6a is. By reflecting the rays of light falling through the mesh at the reversing reflector 7, which return on the same path through the tissue, arises by deflection at the partially transparent mirror 4 and at another mirror 8 Image of the illuminated measuring area 6a, in the plane of the diaphragm 9. This is a Slit diaphragm whose longitudinal axis is perpendicular to the plane of the drawing and whose width equal to or approximately equal to the image width of a fabric thread or a fabric mesh is. When the partially transparent mirror 4 is rotated through a mirror not shown The drive motor moves the image of the measuring area delimited by the diaphragm 3 across the slit diaphragm 9, with light always passing through the diaphragm slit falls when a mesh gap is shown there and no light falls when a thread of fabric is imaged. The photoreceiver lo thus produces a series of electrical pulses which are amplified in the amplifier 13. The opening of the Photo receiver is in the order of magnitude of the mesh size or the image of this Mesh size.

With a constant geometric arrangement, the size of the measuring area depends on the fabric web 6 clearly with the angle of rotation of the mitldem partially permeable Mirror 4 rigidly connected code disk 11 together. By the measuring device 12 a pulse number n can thus be tapped, which is stored in the reducer 14, for example is divided down in the ratio n: 1 and then the gate 15 closes again, which opened at the start of counting. The counter 16 thus receives a number of pulses paid by the amplifier 13, which the Number of stitches in the through Code disk 11, device 12, coaster 14 and gate 15 delimited tissue area 6a corresponds. The display can correspond, for example, to the number of meshes per cm of fabric. A control signal can be used for control purposes through a subsequent digital-to-analog conversion of tissue transport can be derived, whereby not only measured, but also can be targeted in terms of keeping the mesh size constant.

Claims (8)

Claims 1. Mesh size measuring device for sieve fabrics and other fabric webs characterized in that by means of an optical beam path (1-5) from the Sieve fabric (6) a limited measuring area (6a) is illuminated and enlarged from it Image by means of a slit diaphragm (9) by relative movement of the light and dark areas successively made accessible to a radiation receiver (lo) and its light-dark reactions be recorded in a counter (16) to then e.g. for display, registration, Signaling or regulation to be processed further. 2. Measuring device according to claim l), characterized in that in the optical beam path (1-5) a partially transparent, oblique to the beam path standing mirror (4) installed and behind the illuminated measuring area (6a) Reflector (7) is arranged so that the rays passing through the tissue thrown back in the same way and separated from the mirror (4). 3. Measuring device according to claim 1) and 2), characterized in that that the partially transparent mirror (4) is movably arranged, in particular by a Motor is designed to be rotatable and, through its movement, the image of the measuring district (6a) past the slit diaphragm (9). 4. Measuring device according to claim i) to 3), characterized in that that the respective angle of rotation of the partially transparent mirror (4) via a code disk (11) and a display device (12) signals and the signal via a reduction device (14> used to determine the opening time of a gate (15) to the counter (16) will. 5. Apparatus according to claim 1) - 4), characterized in that a deflecting mirror in the beam path from the rotating mirror (4) to the slit diaphragm (9) (8) is switched on in such a way that the beam passing through the diaphragm is parallel to the beam path (1-5). 6. Measuring device according to claim l), characterized in that there is a slit diaphragm (9) and radiation receiver (1o) are movable over the image of the measurement area. 7. Measuring device according to claim 1), characterized in that the Image of the illuminated measuring area (6a) projected onto a transparent plate is behind the slit diaphragm (9) and radiation receiver (10) for scanning move. 8. Measuring device according to claim 1) - 7), characterized in that with the part moving for scanning a signaling or disconnecting device for the end of the scanning process is connected. Blank page