SIST EN 16845-1:2017

2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.UELUDQLKPhotocatalyse - Activité chimique anti-salissures à l’aide de matières organiques adsorbées dans des conditions solide/solide - Partie 1 : Colorants sur des surfaces poreusesPhotocatalysis - Anti-soiling chemical activity using adsorbed organics under solid/solid conditions - Part 1: Dyes on porous surfaces25.220.20Površinska obdelavaSurface treatmentICS:Ta slovenski standard je istoveten z:EN 16845-1:2017SIST EN 16845-1:2017en,fr,de01-maj-2017SIST EN 16845-1:2017SLOVENSKI
STANDARD
EUROPEAN STANDARD NORME EUROPÉENNE EUROPÄISCHE NORM
EN 16845-1
March
t r s y ICS
t wä t t rä t r English Version
Photocatalysis æ Antiæsoiling chemical activity using solid conditions æ Part
sã Dyes on porous surfaces Photocatalyse æ Activité chimique antiæsalissures à l 5aide de matières organiques adsorbées dans des surfaces poreuses
Photokatalyse æ Schmutzabweisendeá chemische Aktivität unter Verwendung adsorbierender Farbstoffe auf porösen Oberflächen This European Standard was approved by CEN on
s v November
t r s xä
egulations which stipulate the conditions for giving this European Standard the status of a national standard without any alterationä Upætoædate lists and bibliographical references concerning such national standards may be obtained on application to the CENæCENELEC Management Centre or to any CEN memberä
translation under the responsibility of a CEN member into its own language and notified to the CENæCENELEC Management Centre has the same status as the official versionsä
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B-1000 Brussels
t r s y CEN All rights of exploitation in any form and by any means reserved worldwide for CEN national Membersä Refä Noä EN
s x z v wæ sã t r s y ESIST EN 16845-1:2017

Typical Experimental Data . 21 A.1 General . 21 A.2 Optimization of the Spraying Conditions (example) . 21 A.3 Measurement of the Spraying Mass Flows (example) . 22 A.4 Measurement of the Covered Area (example) . 23 A.5 Evaluation of the Dirt Parameter Calibration Function (example) . 25 A.6 Evaluation of the Self-cleaning Effect (example) . 27 Bibliography . 29
UVVISIR radiation 3.3 spraying distance distance from the outlet of the spraying gun (see experimental setup) and the surface of the test sample SIST EN 16845-1:2017

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13,5% of the maximum intensity 3.5 dirt parameter DP dye amount spread or persistent over the sample surface 3.6 dirt parameter calibration function mathematical function that describes the relation between the Dirt Parameter and the amount of dye spread over the sample surface 4 Symbols and abbreviations a, b, c polynomial constant parameters obtained by the fit using Formula (7) Anet
CA Covered Area (cm2) Cdye concentration of the dye in the spraying solution (g cm–3) dac density of acetone at the temperature of the measurement (g cm–3) DP dirt parameter (nm): the parameter is indexed depending on the context DR deposition rate (g s–1 cm «2) f volumetric spraying flow (cm3 s–1) Fi mass flow (g s «1) kdye first order kinetic constant of the specified dye for the photocatalytic self-cleaning process (min–1) MW molecular weight n number of steps used for deposition of the dye on the sample surface; typically, n = 5, but can be larger if the surface is excessively wet
spei and j referring to steps of spraying and illumination, respectively Rbackground
SC standard dye covering defined in Table 2 (g cm «2) T temperature in °C ti irradiation time in min tspr spraying time (s), calculated as tspr = sprstdt/n W the full width at half maximum (FWHM) of the sprayed dye colour peak (cm)
average covering of dye at the surface (g cm–2); indexes i and j refer to steps of spraying and illumination, respectively o maximum average covering of dye at the surface (g cm–2), obtained at sprstdt SIST EN 16845-1:2017

wavelength (nm) max wavelength (nm) at which there is a maximum of absorbance sprstdt standard spraying time (s) τ1/2dye half-life of the dye for the photocatalytic self-cleaning process (min) 5 Principle This standard concerns the comparison and the quality assurance of photocatalytic materials used as self-cleaning materials. The method described is intended to measure the photocatalytic self-cleaning performance of a photocatalytic material by evaluating its ability to clean its surface, previously covered by a known amount of coloured organic compound, as a consequence of the exposition to ultraviolet light. A controlled amount of a dye solution dissolved in a volatile solvent (acetone) is spread on the tested surface by using a spraying gun. The photocatalytic material turns out to be covered by the solid dye. The relation between the amount of the spread dye and the spectrophotometric reflectance is defined in the calibration step. The calibration function involves the measurement of the reflectance spectra of the sample surface as a function of the dyes covering. Dyes used in separate experiments are Metanil Yellow, Rhodamine B, and Methylene Blue. The test shall be carried out with the dye showing the maximum optical contrast with the material to be tested. Criteria for the choice of the best dye are here given (see 8.3.2). Optionally, the test can be carried out with the others dyes as the reactivity of each dye can depend on the specimen. The measurement with more than one dye is encouraged, but it is not compulsory. The self-cleaning activity measured by this test shall be referred to the used dye. The soiled surface is then irradiated in air by UV-A light under defined conditions and the decrease of the dye amount on the surface is monitored by measuring the reflectance spectra of the surface of the test sample in the visible range. By using the calibration function the change of the reflectance spectra can be related to the kinetic of disappearance of the dye from the surface. The photocatalytic self-cleaning performance is determined as the half-life (minutes) of the dyes applied to the surface. 6 Instruments 6.1 Spraying system The method described in this standard relies on the possibility to cover the sample surface with the dye in a controlled way. A spraying system shall be used to spread over the sample surface a solution of the dye (dye solution) in volatile solvent (acetone). The spraying system consists of a sample support and in a pneumatic system under pressure able to spray the dye solution over the sample for different definite times. The dye solution shall be spread by using a spraying gun that forms a circular spot. This involves a normal (Gaussian) distribution of the amount of dye centred in the spot of the dye on the surface. The amount of solution spread over the test sample is controlled by changing the spraying time (tspr) with a timer that opens and closes, with a precision of ± 0,01 s, the dye solution flow. The relative distance and orientation between the gun and the sample shall be changed in a way to obtain a symmetric covering of the surface of the test sample and the desired surface covered area. Due to the normal distribution of the colour intensity at the test piece surface, the dye surface covered area is defined as the area of the sample where the colour intensity is
·
% of the maximum intensity (see 8.2). The optimal distance from the gun outlet to the surface of the test sample is referred as the spraying distance. A sketch of the pneumatic spraying system and of the sample support is shown in Figure 1 and Figure 2. SIST EN 16845-1:2017

Key A (N2) actuator gas line (N2) A air atomization AIR A tressurized bottles Aw water Ad dye/dyes solution B spraying gun 123 digital timer EV electrovalve GR gas regulator with manometer GT gastap pair pressurized AIR S sample V(N2) vent gas line (N2) Figure 1 — Pneumatic spraying system SIST EN 16845-1:2017

Key A position of the spraying gun B sample arrows forward or back, up or down translation of the sample position Figure 2 — Sample support The spraying distance between the gun and the sample (see Figure 2) is typically fixed after setup of the instrumentation (see 8.2); the test samples are placed orthogonally to the spraying flow direction. The spraying gun shall provide a circular sprayed spot. Using a 0,8 mm fluid nozzle orifice under the given pressure, the typical spray distance is 200 mm. Typically, the fluid flow through the gun shall be regulated to obtain a value close to 0,2 cm3 s–1. For the accurate measurement of the spraying flow see 8.2.2. The atomization air flow is typically (270 ± 20) N dm3 min–1. The system shall be operated under a ventilated chemical hood. Safety precautions shall be taken for use of acetone (CAS No: 67-64-1) such as safety glasses, good ventilation, removal of sources of ignition from the working area. 6.2 Analytical balance An analytical balance with the precision of 10 «4 g is used for all the gravimetric operations. SIST EN 16845-1:2017

¶ 3 nm. The reflectance spectra are measured by using a diffuse reflectance standard such as BaSO4 as a reference of 100 % reflectance material. 6.4 Light source The light source should agree with CEN/TS 16599. It shall provide UV-A irradiation within a wavelength range of 345 nm to 385 nm for a specimen containing TiO2. Suitable sources include the so-called black light (BL) and black light blue (BLB) fluorescent lamps, with a maximum at 351 nm or 368 nm, and xenon arc lamps with optical filters that block radiation below 345 nm. In the case of xenon arc lamp, a cooling system shall be used. The test sample shall be irradiated uniformly. The distance between the light source and the sample shall be adjusted so that the UV irradiance (300 nm to 400 nm) at the sample surface is (20 ± 0,5) W m–2. A UV radiometer in conformity with CEN/TS 16599 shall be put at the same distance as the surface of the test sample to be tested. The irradiance along the length of the test sample shall also be constant within ± 5 %. The temperature of the sample during the test shall be (25 ± 5) °C. 6.5 Other experimental needs a) A bottle with a neck diameter larger than the spot dye spot size, as determined under b) in 8.2.3. b) Ventilated chemical hood. c) Sonication bath. d) Safety glasses. e) Vial (from 20 ml to 30 ml in
volume) for use in a) and c) in 8.2.3. 7 Materials 7.1 Dyes used Three different dyes can be used in the test (see Table 1). The dyes shall be dissolved in acetone (2-propanone), a volatile organic solvent that allows a perfect solubilisation of the dyes. The dyes have different optical contrast on the test sample depending on their colour. When a dye is chosen, a calibration function shall be performed (see 8.3). Depending on the effective test sample chromatic properties and the obtained calibration function, the proper dye is selected. SIST EN 16845-1:2017

· 7 cm x 7 cm) or circular (diameter
· 7 cm). The thickness of the test sample can changed as it is not relevant. The right distance from the light source to obtain the specified light power intensity as outlined in 6.4, and the right distance from the spraying gun (see below in 8.
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