DE10326489A1 - Water absorption and wetting properties measuring device for use with absorbent paper, e.g. hand towels or diapers, comprises computer controlled optical imaging equipment together with frame-grabbing and image processing personal computer - Google Patents

Abstract

Water absorption measurement device for hygiene paper, has a sample holder (2) with a transparent, thin and planar object support (3) and film-type electroluminescent surface lamp (4) together with a controlling microcomputer (7). A microprocessor-controlled precision dosing pump (21) is used to apply a test liquid (19) via a dosing cannula (12). A personal computer (PC) (17) with a frame-grabber card and image processing software is used to record a test. An independent claim is made for a device for measuring the wetting properties of material surfaces, especially hygiene paper that has a video camera for measuring the angle of the edge of a droplet on the paper surface.

Description

The The invention relates to a device for measuring the water absorption and the wetting properties of absorbent tissue such as Pulp tissues, Paper towels, Tissue, diapers and the like.

to Assessment of quality and uses of absorbent sanitary papers is the knowledge of receptivity of liquids required by the physical or chemical nature dependent is. For testing the absorption capacity of absorbent sanitary papers one proceeds according to a known method mostly in accordance with DIN 54 540 part 4 in such a way that one test sample of a certain size with the receiving liquid wetted and by weighing before and after wetting the weight difference determined. That way the weight of the liquid delivered to the sample when moistened while determining the receptivity of the Hygiene paper for the liquid However, it is only inaccurately determined because the tissue papers at wetting in this way because of fluctuating wetting conditions Liquid in different amount is allocated, so that after wetting or when weighing one more hygiene paper, the other sanitary paper less unaccumulated liquid adheres. Also, the speed with which the liquid is recorded, leaves can not be determined with certainty in this way. When examining the receptivity of hygiene papers for liquids However, it depends on both the amount of liquid absorbed per square centimeter as well as the recording speed.

In In practice, therefore, absorbing tissue absorbs absorption time for the Water absorption measured with a stalagmometer. For the measurement The Absorbierzeit becomes from a defined height a drop of water on the Sample dripped and with a stopwatch the time from striking up to the full Absorbance measured. In this way, the measurement of water absorption of absorbent tissue according to COBB DIN EN 20 535 because of short breakthrough time extraordinarily difficult and expensive.

In the DE 101 28 643 A1 For example, there is described an apparatus for photoelectrically testing the sizing and absorbency of samples of paper, paperboard, filter material or other absorbent material by means of a test liquid and using a sample placed horizontally in a test plane which is held in place by an elastic pressure ring. The sample is wetted with test liquid to measure absorbency on the underside, the degree of sizing being measured by changing the reflectance with a light receiver.

With the said device leaves Although the breakthrough time can be measured well, the sample of an absorbent However, sanitary paper sucks uncontrollably with the test liquid full. The reason for that lies in the big one Water absorption of the sample and the associated large expansion, the partially until the dissolution the sample goes. The said device is therefore only partially suitable for measuring water absorption and only for firmer and less absorbent Hygiene papers with lower absorbency. Also the measurement of the absorption time and measuring the structural absorption of test ink after DIN 53 126 is due to the known testing equipment for testing the sizing the properties of the hygiene papers mentioned overall not good manageable.

The The object of the present invention is a device to create an automatic, less elaborate determination of water absorption of tissue papers using optical methods, to the handling of the samples in absorbent tissue simplify and improve measurement accuracy. simultaneously intended to measure the absorption time and the measurement of the absorption capacity be carried out by water in one and the same operation, about productivity of the procedure. This object is achieved by a device according to claim 1 and a Device according to claim 8 solved.

By the inventive design of a Apparatus for measuring the absorption time and the absorption capacity of water with an image capture process results in a series of benefits, because the Absorbierzeit and the water absorption a sample can only be measured with a single drop. Thereby can the measurement results by a higher Accuracy to be improved. This results between the individual Samples a more factual comparability and subjective influences can at Assessment of quality and the uses of absorbent sanitary papers are completely avoided. The Test duration can be shortened by approx. 50%. Because of the engagement the test fluid The tissue is not completely in the form of drops the test fluid soaked. It can not soften that way consistently, leaving the sample from an absorbent tissue paper is still easy to handle.

By a basically minor development of the invention with a special sample holder and a second video camera can except the measurements of the wetting properties of tissue papers are carried out. These measurements can also be performed on other material surfaces. The invention thus enables a measurement of the contact angle and the displacement of the vertex of a drop on a material sample. Along with this, the invention makes it possible to measure the wetting rate, the wetting area and the wetting time in relation to the edge angle profile of a test liquid.

The Invention will be described below with reference to an embodiment with reference closer to the drawings explained become. Advantageous embodiments of the invention will become apparent from the dependent claims. In detail shows

1 a device for measuring the water absorption of hygiene papers,

2 an object holder in plan view with reference surface for measuring the water absorption,

3 a device for measuring the wetting properties of material surfaces and

4 a representation of the dynamic contact angle at a drop of a test liquid on the surface of a material sample in a schematic representation.

The assessment of the quality of absorbent tissue by measuring water uptake is performed on tissue paper towels, paper towels, tissue, diapers, white and colored tissue papers, household tissues, blotter papers, napkins, and consumer pulp. Of the hygiene papers to be examined, a sample 1 cut to a size of 100 mm by 100 mm and pretreated according to DIN 53 102.

The below as a sample 1 designated blank of the measured hygiene paper is on a sample holder 2 Placed, with a transparent, very thin and flat slide 3 is provided. The sample holder 2 comprises a sheet-formed electroluminescent surface light 4 for flat and homogeneous illumination of the sample 1 , The electroluminescent area light 4 ensured together with the translucent slide 3 a homogeneous light output with a flat light emission surface. In this way, a comparatively large area can be uniformly illuminated. Electroluminescent lamps emit only extremely low heat, leaving the sample 1 is not heated during the measurement. With the slide 3 is a temperature sensor 5 connected, which monitors the temperature of the absorption process during the measurement time.

Usually, depending on the color of the sample 1 the radiation range of the electroluminescent surface light 4 selected. Surprisingly, it was found that the measurement also with a monochromatically radiating electroluminescent surface light 4 can be carried out. Despite differently colored hygiene papers, it is not absolutely necessary to use the spectral color of the electroluminescent surface light 4 to change. This results in a significant simplification in the construction of the measuring device result.

The electroluminescent area light 4 is with the control electronics 6 connected by the microcontroller 7 is controlled. The in 1 illustrated microcontroller 7 takes over the user guidance via a display 8th with the keypad 9 as well as the control of the entire measuring process and the measured value processing of the temperature sensor 5 determined temperature values.

Within the measuring surface of the slide 3 of 100 mm × 100 mm is after 2 a reference surface 11 of 80 cm ² arranged. The reference surface 11 is in the slide 3 circularly engraved and serves for the exact calculation of the wetting area 17 the sample 1 ,

How farther 1 can be seen, the device for measuring the water absorption comprises a dosing 12 as well as a video camera 13 and a personal computer 14 equipped with a frame grabber card and image processing software.

The measurement of the water absorption takes place with the video camera 13 , a CCD color camera, which is at a fixed distance to the sample 1 is arranged. The depth of field is chosen so that even thicker samples 1 be shown sharp. About a video cable 15 is the video camera 13 with the video input of a frame grabber card on the personal computer 14 connected.

The personal computer 14 with Framegrabberkarte is equipped with a video software for processing the video measurement signals. The frame grabber card provides a system for digitizing, compressing, editing and playing video sequences for the personal computer 14 For example, individual images can be digitized, compressed and edited as bitmaps. The analog video data of the video camera 13 are digitized via the frame grabber card and in the main memory of the personal computer 14 stored. With the Vi deosoftware becomes first the reference surface 11 measured. On this reference surface 11 become the wetting surfaces 17 a drop 18 the following pictures. The measuring process is repeated until the wetting area 17 no longer enlarged. After completion of the measuring process receives the microcontroller 7 from the personal computer 14 the command, the electroluminescent area light 4 off. The water absorption according to Cobb with the measured values and the input value for the droplet size as well as the absolute water absorption per mm ² is calculated.

The soaking time is measured and from this the wetting speed is calculated.

The image analysis is done with a on the personal computer 14 also existing installed software with which the images are stored and displayed on the screen 16 of the personal computer 14 be displayed with magnification. The image analysis software enables the automatic, quantifiable evaluation of the measured images and the recognition of complex structures and the calculation of defined characteristic values. In addition to the analysis of the surface area, the image analysis software also allows the evaluation of further object properties such as the circumference or maximum diameter of a drop 18 the test fluid 19 ,

For making a drop 18 a test liquid 19 is a precision metering pump 21 with a dosing cannula 12 intended. The dosing cannula 12 and the container 22 for the test fluid 19 are on a level and are with a scalable fine drive to the surface of the sample 1 in the range of 20 mm to 80 mm infinitely adjustable in height attached to a holder not shown. As a holder, for example, serve a rack or a vertically oriented spindle, which is offset from the slide 3 is arranged. The adjustment range is identical to the drop fall height h. The dosing cannula 12 is so dimensioned and honed that drops 18 of the size 0.005 ml can still drain. To avoid the dripping is the to the dosing cannula 12 leading supply line 23 U-shaped with a siphon-like curvature 24 formed, which has the advantage that it works like a siphon. The supply line 23 leads to a digital microprocessor-controlled, interoperable precision metering pump 21 that with the container 22 for the test fluid 19 and circuitry for driving with an associated control computer 25 connected is. With the microprocessor-controlled precision metering pump 21 All dosing tasks can be carried out in the microliter range. The controller takes over the microcontroller 7 that with a standard interface 26 with the control computer 25 the digital precision metering pump 21 connected is. The delivery rate can be adjusted via the stroke length or the stroke frequency by an exact resolution in single strokes. In the microcontroller 7 The dosing steps are calculated on the basis of the drop size and the control computer 25 for the precision metering pump 21 handed over for execution.

All with the test liquid 19 Modules coming into contact are largely resistant to aggressive media, so that other test liquids than water can be used.

In the following, the measurement of the water absorption of sanitary papers will be described. The microcontroller 7 comes with the interface cable 27 and the video camera 13 with the video cable 15 with the personal computer 14 connected. Both devices are switched on and report with their respective user interface. The operation of both devices is menu driven. On the display 8th of the microcontroller 7 the operator is prompted to select the water intake measurement option and enter the drop size value in ml. During the selection of the measurement option, the video channel is automatically switched to the video camera 13 triggers and the user interface for water intake at the personal computer 14 called. Thereafter, the request for the manual setting of the entered drop fall height h occurs.

With the confirmation of the prompt Start on the display 8th of the microcontroller 7 becomes the electroluminescent area light 4 switched on and there is the measurement of the reference surface 11 , Thereafter, the request is made the pretreated sample 1 insert and start the measurement. After all operating steps have been completed, the measurement is triggered via the keypad 9 ,

In the microcontroller 7 The dosing steps are calculated on the basis of the drop size and the control computer 25 for the precision metering pump 21 handed over for execution. When the measurement is triggered, the commands are sent to the control computer 25 the digital precision metering pump 21 with the dripping and to the personal computer 14 to start with image processing. When the drop 18 touches the sample surface, the time measurement takes place. The image processing is completed when the wetting area 17 no longer enlarged. The microcontroller 7 gets from the personal computer 14 the command to stop the other measuring routines, the electroluminescent surface light 4 turn off and prompt the operator to take the sample 1 refer to.

Meanwhile, the personal computer has 14 from the measured images the Durchtränkungs time, wetting speed and wetting area 17 and Cobb's water uptake with the measurements and the input value for the drop size and the absolute water absorption of the wetting surface 17 calculated in g / mm ² . The measured and calculated values are entered in the measurement log and stored with the trial typical data, the values of the temperature measurement and the first and last image. Thereafter, the request is made to trigger a new measurement.

The measurement of the wetting properties of material surfaces is carried out according to 3 essentially according to the same procedure, wherein for the measurement of the contact angle φ a second video camera 31 and for the optical illumination of the drop 18 an electroluminescent area light 34 laterally next to the drop 18 at the level of the optical axis of the second video camera 31 is arranged.

The present in foil form electroluminescent surface light 34 is in 3 When viewed in cross-section, it is preferably bent in a parabolic or ellipse-like manner and standing vertically on the sample holder 2 arranged. The electroluminescent area light 34 is the second video camera 31 arranged opposite. To make an accurate measurement of the drop 18 To be able to make, lies the surface of the sample holder 2 in the optical axis of the second video camera 31 , The drop 18 a test liquid 19 is located near the focal point of the parabolically curved electroluminescent surface light 34 , The drop 18 the test fluid 19 is thus illuminated completely diffuse.

The wetting and drop shape of a lying drop 18 are the ratio of the adhesion forces between the tissue paper as a material sample 32 and the liquid and cohesive forces in the liquid, with surfactants reducing the surface tension. On absorbent materials, the contact angle φ changes constantly as a function of time. In order to measure the dynamic edge angle or the absorption rate and the propagation, it is important to record a sequence of images during this time. After the drop 18 on the material sample 32 has been applied, the dynamic contact angle can be calculated independently of all operating influences on the basis of these images.

It is important that the drop 18 careful to the test 1 is applied to ensure that the contact angle can be kept as large as possible. When the drop 18 during application in the material sample 32 is pressed in, creates a smaller contact angle φ. drops 18 with the test liquid water can be applied from a height of 2 mm without appreciable influences.

For this reason, it is advantageous if the sample holder 2 is constructed so that with the described scaled fine drive a minimum drop drop height h of 2 mm is adjustable. The drop height h is adjustable between 2 mm and 80 mm. In this measurement method is the first video camera 13 off. The drop 18 to 4 is with respect to the edge angle φ and the shift of the vertex Sv from the second video camera 31 measured at 25 fps. In 4 is the definition of the edge angle φ and the displacement of the vertex Sv illustrated graphically.

With the image sequence of the second video camera 31 the wetting time and the wetting speed are calculated.

The following describes the measurement of the wetting properties of material surfaces. The microcontroller 7 comes with the interface cable 27 and the video cable 33 the second video camera 31 with the personal computer 14 connected. Both devices are switched on and report with their respective user interface. The operation of both devices is menu driven. On the display 8th of the microcontroller 7 the operator is prompted to select the measurement option for the wetting properties of material surfaces and to enter the value for the drop size in ml.

By selecting the measurement option, the video channel is automatically switched to the second video camera 31 and calling the user interface for the wetting properties of material properties on the personal computer 14 , This is followed by a request to manually set the drop drop height entered and the trial typical data on the personal computer 14 enter. With the confirmation of the prompt Start on the display 8th becomes the parabolic electroluminescent panel light 34 switched on. Thereafter, the request is made, the pretreated material sample 32 insert and the measurement via the keypad 9 to start. The material sample to be examined 32 is cut to a size of 40 × 40 mm ² . It should be flat and pretreated in accordance with DIN 53 102. In 4 is highly schematized example, a material sample 32 represented by a two-sided coated inkjet paper with 100 grams of weight.

In the microcontroller 7 the dosing steps are calculated on the basis of the drop size and the control computer 25 for the precision metering pump 21 handed over for execution. At the same time begins the second video camera 31 with image processing. When the drop 18 the surface of the material sample 32 touched, the time is measured.

The image processing is completed when the extension of the drop 18 no longer enlarged. The microcontroller 7 gets from the personal computer 14 the command to stop the other measuring routines, the electroluminescent surface light 34 turn off and prompt the operator to take the material sample 32 refer to.

Meanwhile, the personal computer has 14 from the measured images, the contact angle φ, the shift of the vertex Sv, the wetting speed with respect to the contact angle and the wetting surface 17 calculated. The measured and calculated values are entered in the measurement log and stored with the trial typical data, the values of the temperature measurement and the first and last image. Thereafter, the request is made to trigger a new measurement.

The advantages of the proposed method are that when using an electroluminescent surface light 4 or a parabolically curved electroluminescent surface light 34 with a homogeneously radiating luminous area a slight heating of the sample 1 or the material sample 32 and the drop 18 the test fluid 19 to be recorded. As a result, the accuracy of the measurement results can be considerably increased because the test duration for determining the wetting properties is considerable. The invention further has the advantage that the measurement of the wetting properties and measurement of the water absorption of hygiene papers is made possible side by side without much effort.

at Some sanitary papers often have a poor initial wetting behavior to record. For the assessment of quality and the possibility of use of absorbent sanitary papers, therefore, it is extraordinary useful, one appropriate knowledge of the absorption capacity of liquids and the initial wetting behavior at the same time, which to accomplish with the help of the present invention precisely and without difficulty is.

Claims (15)

Apparatus for measuring the water absorption of hygiene papers, characterized by a sample holder ( 2 ) with a transparent, thin and flat slide ( 3 ) and a sheet-formed electroluminescent surface light ( 4 ) as well as a microcontroller connected to this control technology ( 7 ) for the control of the measuring processes, for the operator guidance via a display ( 8th ) with the keypad ( 9 ) and control technology with the control computer ( 25 ) of a microprocessor-controlled precision metering pump ( 21 ) and one to a personal computer ( 14 ) connected video camera ( 13 ), wherein the precision metering pump ( 21 ) a container ( 22 ) for the test fluid ( 19 ) and a dosing cannula ( 12 ) making a drop ( 18 ) of a test liquid ( 19 ) and the personal computer ( 14 ) is provided with a Framegrabberkarte and image processing software. Apparatus according to claim 1, characterized in that the video camera ( 13 ) for measuring the water absorption at a fixed distance to the sample ( 1 ) and a depth of field corresponding to the thickness of the sample ( 1 ) Has. Apparatus according to claim 1 to 2, characterized in that the personal computer 14 equipped with frame grabber card with a video software for processing the video measurement signals, wherein the analog video data digitized as frames on the framegrabber card, for example as bitmaps and in the main memory of the personal computer ( 14 ) are stored. Device according to claims 1 to 3, characterized in that with the slide ( 3 ) a temperature sensor monitoring the temperature of the absorption process ( 5 ) connected is. Apparatus according to claim 1 to 4, characterized in that the slide ( 3 ) within the measuring area of 100 mm × 100 mm into the slide ( 3 ) circularly engraved and the exact calculation of the wetting area ( 17 ) of the sample ( 1 ) serving reference surface ( 11 ) of 80 cm ² . Apparatus according to claim 1 to 5, characterized in that the dosing cannula ( 12 ) of the precision metering pump ( 21 ) for making a drop ( 18 ) of a test liquid ( 19 ) with a scalable fine drive for adjusting the drop height (h) with respect to the surface of the sample ( 1 ) is arranged in the range of 20 mm to 80 mm infinitely adjustable in height. Apparatus according to claim 1 to 6, characterized in that the to the dosing cannula ( 12 ) leading supply line ( 23 ) U-shaped with a siphon-like curvature ( 24 ) is trained. Device for measuring the wetting properties of material surfaces, in particular of hygiene papers, characterized by a second video camera ( 31 ) for the contact angle measurement of a drop ( 18 ) and one with the surface in the optical axis of the second video camera ( 31 ) lying sample holder ( 2 ) for a material sample ( 32 ) with one side beside the drop ( 18 ) at the level of the optical axis of the second video camera ( 31 ) arranged electroluminescent surface light ( 34 ) for the optical illumination of the drop ( 18 ) with a microcontroller ( 7 ) is connected in terms of control technology, wherein the microcontroller ( 7 ) for the control of measuring processes and for operator guidance via a display ( 8th ) with a keypad ( 9 ) and control technology with the control computer ( 25 ) of a microprocessor-controlled precision metering pump ( 21 ) and to a personal computer ( 14 ) connected second video camera ( 31 ), wherein the precision metering pump ( 21 ) a container ( 22 ) for the test fluid ( 19 ) and a dosing cannula ( 12 ) making a drop ( 18 ) of a test liquid ( 19 ) and the personal computer ( 14 ) is provided with a Framegrabberkarte and image processing software. Device according to claim 8, characterized in that the electroluminescent surface light (FIG. 34 ) seen in cross-section preferably parabolic or ellipse-like bent and standing vertically on the sample holder ( 2 ) is arranged. Apparatus according to claim 8 to 9, characterized in that the electroluminescent surface light ( 34 ) of the second video camera ( 31 ) is arranged opposite one another. Apparatus according to claim 8 to 10, characterized in that the drop ( 18 ) of a test liquid ( 19 ) near the focal point of the parabolically curved electroluminescent surface light ( 34 ) is arranged and completely diffused illuminated. Apparatus according to claim 8 to 11, characterized in that the personal computer ( 14 ) is provided with a frame grabber card with a video software for processing the video measurement signals, wherein the analog video data digitized as frames on the framegrabber card, for example as bitmaps and in the main memory of the personal computer ( 14 ) are stored. Apparatus according to claim 8 to 12, characterized in that the sample holder ( 2 ) with a temperature sensor monitoring the temperature of the absorption process ( 5 ) is provided. Apparatus according to claim 8 to 13, characterized in that the metering cannula 12 the precision metering pump ( 21 ) for making a drop ( 18 ) of a test liquid ( 19 ) with a scalable fine drive for adjusting the drop fall height (h) with respect to the surface of the material sample ( 32 ) is arranged in the range of 2 mm to 80 mm infinitely adjustable in height. Apparatus according to claim 8 to 14, characterized in that the to the dosing cannula ( 12 ) leading supply line ( 23 ) U-shaped with a siphon-like curvature ( 24 ) is trained.