Direct Evaluation Method of UV Curing Process on the Basis of Conductivity Change of Photopolymerization Materials

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IS&T's IS&T s th Annual Conference Direct Evaluation Method of UV Curing Process on the Basis of Conductivity Change of Photopolymerization Materials Yasusuke Takahashi, Sunao Tada, Shoutaro Yamada Department of Electro-Photo-Optics, Tokai University, Hiratsuka, Kanagawa, Japan Abstract A novel evaluation method is proposed for UV curing of photopolymerization materials. The method is based on the measurement of photodecrease of the conductivity, which is caused by the photopolymerization of acrylate monomer during the curing process of the ink film. The current changing rate by UV irradiation is in proportion to relative hardness of ink layer in the surface type cell. The evaluation of sensitivity and curing mechanism of UV curable materials is possible by the measurement of photochange of sample current in either surface or sandwich type cell. The information for non-cured ink layer thickness in the surface type cell can be get from the relationship between the initial thickness and the resistivity of ink layer before UV irradiation. In the case of the sandwich type cell, the curing rate of UV curable resin is in proportion to square root of UV intensity and photoinitiator concentration, respectively. These results satisfy the theoretical equation of the photopolymerization. Introduction Now, radiation cured products by UV/EB polymerization process are comprised of coatings, electronics, inks, adhesives and others. The benefits of UV curing are comprised of no solvent emission, low energy requirement, high productivity, product quality and low VOC gener-ation. ) The UV and EB radiation curing market for inks and coatings now are growing. ),3) UV curing of inks and coating is composed of radical photopolymerization which involves initiation, propagation and termination process. Many kinds of ink and coating which have different curing speeds are used in practical production process. UV curing speed or sensitivity has been practically evaluated by the measurements for NMR, IR and / or gelling rate of cured materials. These measurement techniques are very complicated and the measurement process takes a long time. In order to design the most suitable curing system by using UV curing materials and UV light source, it may be required that we have the exact information for UV curing speed of photosensitive materials and spectral and energy data of UV source. Our goal is to develop the simple evaluation method for UV curing speed or sensitivity of photopolymer and to apply the method to a practical UV curing system. In this study, we focused on the conductivity change (negative photoconductivity) of UV curing materials caused by photopolymerization which involves a highly crosslinked system. Experimentals Conductivity Measurement System Figure shows the experimental set-up for the measurement of the conductivity change of UV curable ink layer. Hg short arc lamp (8W) was used. The light was guided by quartz optical fiber and the UV ink sample was illuminated by the guided light through the interference filter (λ = 36nm). Va DC Power Supply Hg Short Arc Lamp 8W (Spot UV) Switch Sample Cell Ammeter A Recorder Interference Filter (36nm) Optical Fiber Figure. Experimental setup for measurement of conduction current in UV curable ink. We used two kinds of cell for the conductivity measurement, that is, surface type cell and sandwich type cell as shown in Figure. The surface type cell had Al electrodes spaced of mm on slide glass as shown in Figure -(a) and UV curable ink was coated at about 9µm thickness on the cell electrodes. The sandwich type cell was composed of two slide glasses having Al electrode deposited on its surface, which were faced each other and was spaced by 9µm polymer film as shown in Figure -(b). The transmittance of Al electrodes was about %. The cell space of 9µm was filled 9

IS&T s th Annual Conference with UV curable ink. The applied voltage to both cells was D.C V, and the circuit current changes caused by UV irradiation were measured. Spacer (9 µ m) UV(36nm) Electrode Space mm a) Surface Type Cell UV(36nm) UV Curable b) Sandwich Type Cell UV Curable (9 µ m) (Thickness less than µ m) (Transmittance %) Figure. Cell configurations. Table. Tested UV ink Maker Types of UV Color DC-Clear 9 L Clear RT-7 Dainippon Chem. (DIC) SEPTER Sakata ACRASET (SKT) Teikoku SERICOL UV FIL (Screen) Hand Made Bisphenol A- diacrylate Benzoin Samples Table shows the list of UV inks used in this study, which mainly involve the process color ink. The chemical composition of DC-Clear 9 L is composed of acrylate monomer, acrylate origomer, photoinitiator (BenzilDimethylketal) and others. The monochrome light of 36nm, was irradiated to samples, because the absorbance of the wavelength range from 3nm to 38nm is caused by the photoinitiator. Results and Discussion Photochange of conductivity of clear UV ink 4) Figure 3 shows the time dependence of the photochanges of sample current in surface type cell at various UV intensities. The sample currents rapidly decrease within sec after UV light-on, and after that, gradually decrease. At any UV intensity, sample current reaches its equilibrium value (Is) after about 3 sec of UV light-on. The value of Is is dependent on UV intensity. In the case of sandwich type cell, the photochange of sample currents decreases more rapidly than that of surface type cell as shown in Figure 4. After about sec from UV light-on, the current decay curves reach all same level in equilibrium value (Is) and Is shows no dependence on UV intensity. It is thought that the difference of UV intensity dependence of Is value between both cells may suggest the existence of difference of information in photopolymerization process obtained by conductivity measurement. 3... 3 UV Irradiation Time t(sec) UV intensity φ (mw/cm ) 8(mW/cm ) 6(mW/cm ) 4(mW/cm ) (mw/cm ) Figure 3. Photochange of sample current in surface type cell by UV irradiation. Parameter is UV intensity (DIC DC-Clear 9L). 8 6 4 4 6 8 UV Irradiation Time t(sec) UV intensity φ (mw/cm ) 8(mW/cm ) 6(mW/cm ) 4(mW/cm ) (mw/cm ) Figure 4. Photochanges of sample current in sandwich type cell by UV irradiation. Parameter is UV intensity(dic DC-Clear 9L). 6

IS&T s th Annual Conference Photochange model of UV ink conductivity It is mentioned in previous section that the curing information contained in conductivity change of curable ink in surface type cell is different from that in using sandwich type cell. The physical meaning of this difference may be explained by the proposed model as follows. UV UV R s Rb Cured Layer Non-Cured Layer R s Spacer (9µm) (Transmittance %) R s R s >> R b R b R s R b a) Surface Type Cell b) Sandwich Type Cell Figure. Model of photochange of the sample current in surface and sandwich type cells. In surface type cell, the resistances in the ink layer are in parallel with the ink surface. Figure -(a) explains the state of some degree of UV curing of ink layer. Some portion of the upper side of ink layer is cured by UV irradiation. The cured ink layer is photopolymerized and have some thickness and the increased resistance R s. On the hand, the inner side of the ink layer is not cured, because sufficient UV light flux to initiate the curing does not reach that portion. The non-cured inner layer have low resistance R b in surface type cell. The resistance R s and R b from parallel circuit as shown in Figure -(a). In this case, it may be thought that the cured layer resistance R s is much larger than non-cured portion resistance R b and the conductivity change data contain only the information of non-cured portion in UV ink layer(r s >>R b ). + d=9 µm Electric line of force layer Electrode Gap l= µm - R b less than µm Figure 6. The model of current flow in the ink layer of surface cell. 3 4 Layer Thickness d(µm) Figure 7. layer thickness vs. current in clear UV ink. Now, we have to discuss the physical meaning of current flow of ink layer in surface type cell. Figure 6 shows the model of electric line of force and current flow in ink layer of surface type cell. At an applied voltage V, total current I is give by I = V R = r V l d ρ = V l Sc ρ, () where R is the layer resistance, r is the width of electrode, l is the gap length between electrodes, d is the ink layer thickness, ρ is the specific resistance of UV ink and S c is the cross section of ink layer (S c =r_~d). Equation () shows that I is in proportion to the ink layer thickness d or the cross section Sc. Figure 7 shows experimental data for the dependence of current I on ink layer thickness d (µm) in UV clear ink and the linear relationship between I and d as indicated by equation (). In the case of surface type cell, the photodecay current I b is governed by non-cured ink layer resistance R b because of R s >>R b as shown in Figure -(a). I b is given by Ib = V R = r V l db ρ where d b is the non-cured ink layer thickness under some UV intensity. We can get the value of the non-cured ink layer thickness d b from equation (), because the values of r, V, l and ρ are known. But d b is the average thickness, because the incident light intensity may not be uniform distribution to the thickness direction. Assuming that d b and d are the cured and initial ink layer thickness, respectively, d is given by () d = d s + d b. (3) 6

IS&T's IS&T s th Annual Conference Table. UV intensity dependency of cured and noncured ink layer thickness of clear UV ink layer UV Intensity (mw/cm ) Cure Layer Thicknes ds (µm) Non-Cured Layer Thickness db (µm). 8..9 8. 6.9. 6. 6.7.3 4. 6.4.6.. 4. 8. 8 7. 7 6. 6. Initial Thickness d=d s +d b =9µm 4. 4 6 8 UV Intensity φ (mw/cm ) Figure 8. Cured ink layer thickness vs. UV intensity Table and Figure 8 shows UV intensity dependence of cured and non-cured ink layer thickness in clear UV ink (d=9µm). It is indicated by these analysis that the photopolymerized layer thickness in UV curable ink is given by the measurement of conduction currents and layer thickness in surface type cell. In sandwich cell as shown in Figure -(b), the resistance R s of upper UV cured ink layer is connected in series to the resistance R b of low non-cured ink layer. R s always is much larger than R b (R s >>R b ). It can be seen by comparing Figure 3 and Figure 4 that total currents of the sandwich layer will be controlled by the series resistance R s of cured ink layer in some thickness. This is reason why the equilibrium current Is does not depend on UV intensity and shows the constant value at some lapse of time. It is suggested that the time dependent change of series resistance of sandwich type cell will be strongly related to the mean curing rate of UV photopolymerization. Dependence of mean curing velocity on UV intensity ) It has been reported that the mean curing velocity Vt of UV curable resin is generally in proportion to a square root of UV intensity and initiator concentration as indicated in equation (4) 6). Vt = kρ [ M] Φηf.33ελ [ P]d kt ( ) = ΛΦ [ P], (4) where φ is the UV intensity, η is the radical generation quantum efficiency by light, f is initiation efficiency of polymerization, ε λ is the spectral absorption coefficient of monomer, d is the thickness, [M] is monomer concentration and [P] is the initiator concentration. Currrent Changing Rate; I It É I t C = I t -I t I I = t (%) I () Curing Velocity; I s V C t = t (%/sec) t UV Irradiation Time t(sec) Curing Sensitivity; Light on S C t = t= = t - φ (%/sec mw/cm ) (7) Figure 9. The definitions of current changing rate, curing velocity and cure sensitivity. Figure 9 shows the definitions of current changing rate, curing velocity and cure sensitivity by using a time dependent curve in photochange of current. Figure shows the relationship between UV intensity φ and curing velocity Vt in surface and sandwitch type cells. It can been seen in the Figure that Vt is in proportion to φ.3 for surface type cell and φ / for sandwich type cell, respectively.... 3 3 UV intencsity φ (mw/cm ) (6) Surface Type Cell Sandwich Type Cell Figure. Relationship between UV intensity f and curing velocity V t Figure shows the relationship between photoinitiator concentration [P] and curing velocity Vt in sandwich type cell. It can been seen in the Figure that Vt is in proportion to [P] /. In the case of sandwich type cell, the curing 6

IS&T s th Annual Conference velocity obtained from photodecay curve satisfies the theoretical equation (4) in ideal case of photopolymerization. 3 3..3 3 Photoinitiator Concentration [P](wt%) Figure. Relationship between photoinitiator concen-tration [P] and curing velocity V t Table 3 Cure sensitivity of tested UV ink Maker Types of UV Color Cure Sensitivity S t= (%/sec mw/cm ) Surface Sandwich DC-Clear Clear 6.68 7. 9L..76 Dinippon RT-7. 4.. 4.9 Chem.6.7 (DIC).8 4.6 SEPTER.7 3.8.64 3.3.9.83 Sakata 3..8 ACRASET.8 3.7 (SKT).67.8.67 6. Teikoku SERICOL 3.9.88 UV FIL.. (Screen).8 3.33 Hand Made Bisphenol A -diacrylate Benzoin.33 *[I]=.wt% Cure sensitivity of UV curable clear and color inks The photochanges of sample current in surface and sandwich type cells were measured for color process UV inks listed in Table. The cure sensitivity S t= is defined as the current changing rate Ct during sec after UV light-on per mw/sec cm of UV intensity(%/sec mw/cm ). The cure sensitivities of all tested UV inks are listed in Table 3. Conclusion This paper has presented a novel direct evalution method of sensitivity and curing process of UV curable materials based on conductivity change. () The amount of photochange of sample current is related to the amount of photopolymerization of curable molecule. () The measured photochange data of sample current contain the information of both cured and non-cured portions of UV curable material layer in surface type cell. (3) The evaluation of curing sensitivity and mechanism of photocurable materials is possible by measurement of photochange of sample current in either surface or sandwich type cell. (4) In practical measurement of negative photocurrent of photocurable materials, the use of surface type cell is desirable, because the preparation of sample and electroded cell are simple and easy. References. J. Howard, Radiation Curing, vol.8, (43) 47 (99).. D. Fishman, UV/EB s & Coatings, American Maker, 49~3 (Sept. 993). 3. K. Tai, UV Printing s, Bulletin of The Japanese Society of Printing Science and Technology, vol.3, 6 (994). 4. S. Tada, Y. Takahashi, etc., New Evaluation Method of UV Curing Process by Change of Electric Conduction, Bulletin of The Japanese Society of Printing Science and Technology, vol.3, 8~34 (99).. S. Tada, Y. Takahashi, etc., A simple Evaluation Method for UV Curing Process by Change of Electric Conduction, The 94 Spring Conference Japanese Society of Printing Science and Technology, 87~9 (June, 8~9, 99). 6. T. Yamaoka, etc., Photopolymer, C.M.C, 8~68 (977). 63

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