Wednesday, May 16, 2012

Water Repellency Test | Bundesmann Water Repellency Test

done by Bundesmann test.   In the test shown in Fig. the fabric is subjected to a shower of water from a head fitted with a large number of standard nozzles. During the shower the back of the fabric is rubbed by a special mechanism which is intended to simulate the flexing effect which takes place when the fabric is worn. 

 









The Bundesmann shower test.

The method is not currently a British standard because considerable variation has been found between different machines, although when tests are carried out on the same machine the variability can be reduced to acceptable levels. 

 

In the test four specimens are mounted over cups in which a spring loaded wiper rubs the back of the cloth while the whole cup assembly slowly rotates. They are subjected for l0 min to a heavy shower whose rate has been adjusted so as to deliver 65ml of water per minute to each cup. The water flow is maintained at 2O0C and between pH 6 and 8. Because of the large amount of water consumed the equipment has to be connected to the mains water supply which leads to difficulties in keeping the water temperature constant. The shower is calculated to have a kinetic energy 5.8 times that of a cloudburst, 90 times that for heavy rain, 480 times that for moderate rain and 21,000 times that for light rain.

Two fabric parameters are determined from the test:
1 Penetration of water through the fabric: the water collected in the cups is measured to the nearest ml.
2 Absorption of water by the fabric: in order to do this the specimen is weighed before the test and then after the shower. To remove excess water the fabric is shaken ten times using a mechanical shaker and then weighed in an airtight container: 






In each case the mean of four values is calculated. 
5 Textile Technology: Water Repellency Test | Bundesmann Water Repellency Test done by Bundesmann test.   In the test shown in Fig. the fabric is subjected to a shower of water from a head fitted with a large number of ...
Tags:

No Comments

***www.TextileTune.blogspot.Com***

< >
Accessories (10) acrylic (1) After treatment (2) Apparel Manufacturing (1) azoic dye (1) basic dye (2) beating (1) blend dyeing (2) Blowroom (5) calculation (2) Cam (1) Campus news (5) carbon fiber (1) Carding (6) Class Lecture (1) color (5) Combing (2) cotton (3) count (3) crimp (1) defects (6) Denim Process (2) Dictionary (26) direct dye (2) disperse dye (11) dye (1) dyeing (15) dyeing auxiliaries (8) dyeing m/c (9) Ebooks (6) Experiment (3) Fabric (4) Fabric Manufacturing (12) Fabric structure (11) Factory (9) fastness (7) Fastness test (7) finishing m/c (4) FlowChart (3) foam dyeing (1) FSD (12) garment dyeing (2) Garments (3) Garments m/c (10) glass fiber (2) hemp (1) inspection (3) Interlinning (1) Interview Q (6) jute (9) jute spinning (13) knit dyeing (1) knitting m/c (21) lecture sheet (1) loom (9) Man made fiber (1) Marchandising (5) milk fiber (1) Modern Textiles (1) mordant dye (1) naphthol dye (1) Needle (2) Others (1) Pattern (2) picking (2) pigment (5) pre-treatment (11) printing amp; finishing (8) printing m/c (1) properties (6) rayon (2) reactive dye (11) Recent News (17) RingFrame (9) Sample (1) seam (1) sewing (3) shedding (3) silk (1) Simplex (6) Sinker (3) sizing (10) Spinning m/c (13) stitch (4) stop motion (4) sulpher dye (9) Technical textile (13) Testing m/c (13) textile definition (7) Textile Industry (1) Textile Physics (2) textiletechnology (18) thread (1) tie dye (1) trimming (1) TTQC (21) twill (4) twist (3) Uster m/c (1) vat dye (4) warp knitting (7) warping (8) washing (2) wastage (2) water (2) Weaving (16) weft knitting (2) Wet Process (1) Winding (11) wool (2) Yarn (30)