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Ultrasonics 38 (2000) 7276 www.elsevier.nl/locate/ultras One-dimensional longitudinaltorsional vibration converter with multiple diagonally slitted parts Jiromaru Tsujino * , Tetsugi Ueoka, Kenichi Otoda, Atsushi Fujimi Faculty of Engineering, Kanagawa University, Yokohama 221-8686, Japan Abstract For increasing the available vibration velocity of the one-dimensional longitudinaltorsional vibration converter, a new type of complex vibration converter with multiple slitted parts installed in the positions avoiding longitudinal nodal positions along the converter for decreasing the maximum vibration stress level at the vibration nodal part was studied. The free end of the converter vibrates in an elliptical or circular locus. Complex vibration systems with elliptical to circular or rectangular to square loci can be applied eVectively for various high-power applications, including ultrasonic welding of metal or plastics, ultrasonic wire bonding of IC, LSI and electronic devices, and also ultrasonic motors. The converter with multiple slitted parts was improved in the vibration stress level and the quality factor compared with the converter with single slitted part. 2000 Elsevier Science B.V. All rights reserved. Keywords: Circular vibration locus; Complex vibration; Complex vibration ultrasonic welding; Longitudinaltorsional vibration converter; Ultrasonic motor; Ultrasonic plastic welding; Vibration converter with diagonal slits 1. Introduction vibration characteristics because the maximum vibration stress along the converter is decreased in comparison to the converter with a slitted part, and the maximumComplex vibration systems with elliptical to circular vibration amplitude of the converter increases signifi- or rectangular to square loci are eVective for various cantly. Vibration locus, and vibration velocity and phase high-power applications. A one-dimensional longitudi- distributions along the converter were measured by two naltorsional vibration converter with a slitted part at laser Doppler vibrometers. The new-type converters longitudinal vibration nodal area driven by a longitudi- were used for ultrasonic plastic welding and ultrasonic nal vibration system is useful for high-power applica- motors. tions including ultrasonic welding of various materials, The maximum available vibration velocity increased ultrasonic wire bonding of bonding of IC, LSI and significantly with the new converter. Welding character- electronic devices, and also ultrasonic motors 14. A istics of plastic materials were improved by the complex new type of converter with multiple slitted parts, for vibration converter. improving the vibration characteristics and increasing The longitudinal and torsional vibration amplitudes the available vibration velocity of the converter, is of a 15 mm diameter of a new converter for an ultrasonic studied. The slitted parts are installed in multiple posi- motor increased to about 12 mm (peak-to-zero value) tions avoiding longitudinal nodal positions along the from 6 mm with a former converter under the same converter for decreasing the maximum vibration stress driving voltage 60 Vrms at 55 kHz. level at the vibration nodal part. Using multiple slitted The converter with multiple slitted parts was found parts, the maximum vibration stress along a converter to be eVective for improving the vibration characteristics decreases and the quality factor increases, and the and increasing the available complex vibration velocity. maximum vibration amplitude increases significantly at the same driving voltage 5. The converter has superior 2. Configurations of vibration converters * Corresponding author. Tel.: +81-45-481-5661; Configurations of two examples of the vibration fax: +81-45-491-7915. E-mail address: tsujinocc.kanagawa-u.ac.jp (J. Tsujino) converters 20 mm in diameter and 79 mm in length, with 0041-624X/00/$ - see front matter 2000 Elsevier Science B.V. All rights reserved. PII: S0041-624X(99)00175-4 73J. Tsujino et al. / Ultrasonics 38 (2000) 7276 4. Complex vibration ultrasonic plastic welding 4.1. Vibration characteristics of a complex vibration converters Fig. 2 shows the relationship between driving fre- quency and longitudinal and torsional vibration velocity of a complex vibration system with the vibration con- verter (a). The driving voltage is kept constant at 20 Vrms. Longitudinal and torsional vibration velocities have maximum values at diVerent frequencies at around 26.3 and 26.4 kHz. The elliptical locus is obtained at the free edge of the converter. Torsional and radial vibration velocity distributions at 26.8 kHz along a complex vibration converter with Fig. 1. Various one-dimensional longitudinal to torsional vibration double slitted parts (a) and (b) are shown in Fig. 3. One converters with double slitted parts. torsional vibration velocity nodal part is within a left slitted area, and the vibration velocities have maximum values at the free edge. The radial vibration velocity distribution along a slitted parts that were installed avoiding a longitudinal complex vibration converter with double slitted parts nodal part, are shown in Fig. 1. The cylindrical longitu- dinaltorsional vibration converters, made of aluminum alloy (JISA7075B), had two slitted parts on both sides of a longitudinal vibration nodal part at its circumfer- ence. The converters were driven by a longitudinal vibration source. Various converters with (a) diVerent and (b) the same angle diagonally slitted parts were made in the trials. The vibration converter part had 18 diagonal slits of 45 or 135, 10 mm width and 0.5 mm width were cut along its circumference using an electrosparking machine. The slit depth was altered from 1.0 to 3.0 mm. The free edge part of the converter vibrated longitudinally and torsionally and vibrated in an elliptical locus. Fig. 2. Torsional and radial vibration velocity distributions along com- plex vibration converters (a) and (b). Driving voltage: 20 Vrms. 3. Vibration characteristics of the converters with two slitted parts The free admittance loops of the total vibration systems with the converters Fig. 1(a) and (b) were measured. The quality factor and motional admittance, |Y mo |, of the vibration system with a converter with diVerent angle slitted parts (a) and the same angle slitted parts (b) were about 600 and 30 mS under welding conditions of two 1.0 mm thick polypropyrene sheets with a static pressure of 890 kPa. The admittance loops of the vibration system with the converters show single circular shapes because the resonance frequencies of the longitudinal and torsional vibrations are close. The quality factors and motional admittances of the both Fig. 3. Relationship between driving frequency, and longitudinal and systems are large. Elliptical loci were obtained at the torsional vibration velocity of a complex vibration system with a vibra- tion converter (A). Driving voltage: 20 Vrms.free edges of the converters. 74 J. Tsujino et al. / Ultrasonics 38 (2000) 7276 (a) is also shown in Fig. 3 (dotted line). A radial and double slitted parts. In the case of the converter with single slitted part, the slitted part is positioned atvibration velocity maximum position means a longitudi- a nodal position of the longitudinal vibration along thenal vibration nodal position, and the longitudinal nodal cylindrical longitudinaltorsional vibration converters.position is positioned between two slitted parts. The On the contrary, in the case of the converter with twotwo slitted areas exist out of the longitudinal nodal slitted parts, the slitted parts are positioned avoiding position where the vibration stress has a maximum value the longitudinal vibration nodal position. The converter along the converter. with diagonal slits is driven by a longitudinal vibration source of two piezoelectric ceramic (leadzircontita- 4.2. Welding characteristics of complex vibration nate; PZT) disks, 15 mm in diameter and 5.0 mm in ultrasonic plastic welding thickness. The vibration converter slitted part has 12 diagonal slits of 45 or 135 and 0.5 mm in width and 10 The relationship between welding time, specimen or 5 mm in length, cut by an electrosparking machine deformed thickness at the welded parts and the weld along the circumference of these converters fabricated strength of the lapped polypropyrene sheets (1.0 mm in from aluminum alloy (JISA7075B). The slit depths of thickness), welded using a 27 kHz complex vibration the 15 mm diameter converter are altered from 1.5 to system with a converter (a) and (b), is shown in Fig. 4. 3.5 mm. The free edge of the converter vibrates longitu- The weld strengths obtained by the system with con- dinally and torsionally and vibrates in an elliptical locus. verter (a) are larger than those with a converter (b). The PZT longitudinal vibration transducers, a longi- The welding time required becomes shorter using the tudinal vibration rod with a flange for supporting the vibration system (a) with a larger torsional vibration motor and a slitted cylinder are clamped by a connecting component. The decrease in specimen deformed thick- bolt. The driving part of the converter and the rotor ness at the welded parts roughly corresponds to the part are statically pressed using corned disk springs by obtained weld strength. Specimens were welded in a a center bolt and nuts. The driving surfaces of the shorter welding time using a complex vibration system converter (JISA7075B) and the rotor (steel: SKD-61 or compared with a longitudinal vibration system. Complex SK-4: tempered) are ground to be flat and smooth using vibration is eVective for ultrasonic welding of plastic 15002000 mesh polishing powder. materials as for metal materials. 5.2. Vibration characteristics of 15 mm diameter ultrasonic motors 5. Ultrasonic motors with a longitudinaltorsional converter The longitudinal and torsional vibration amplitudes at the free edge of these converters were measured by 5.1. Configuration of ultrasonic motors two laser Doppler vibrometers when the driving fre- quency was altered. These converters have near-reso- The configurations of the ultrasonic motors and nance frequencies of the longitudinal and torsional vibration converters, 15 mm in diameter, are shown in vibrations similar to Fig. 2. The largest longitudinal Fig. 5. Fig. 5(a) and (b) show the configurations of vibration amplitudes of the converter of single and two 15 mm diameter motors using a converter with single slitted parts without a rotor part were about 6 and 12 mm (peak-to-zero value) at frequencies of 5055 kHz. The largest longitudinal vibration amplitudes of these converters with a rotor part are about 3 and 9 mmat frequencies near to 55 kHz. The largest vibration ampli- tudes of a converter with double slitted parts are about two to three times compared with the amplitudes of a converter with single slitted part. 5.3. Vibration loci at the driving surface of the converter In these cases, the longitudinal vibration is partially converted to torsional vibration at the slitted parts, and the cylinder part of the converter vibrates longitudinally and torsionally. The vibration locus at the free edge is determined by the vibration phase diVerence between Fig. 4. Relationship between welding time, deformed weldment height these vibrations. Vibration loci at the driving surfaces and weld strength of the lapped polypropyrene sheets (1.0 mm in thick- of longitudinaltorsional converters were measured ness), welded using a 27 kHz complex vibration system with a converter (a) and (b). using two laser Doppler vibrometers (20 MHz) that 75J. Tsujino et al. / Ultrasonics 38 (2000) 7276 Fig. 5. Configurations of 15 mm diameter ultrasonic motors using a longitudinaltorsional vibration converter with single slitted part (a) and double slitted parts (b). detect longitudinal and torsional vibrations indepen- length of the ultrasonic motor of 15 mm diameter in the driving frequency 55.1 kHz (without a rotor) anddently. The vibration locus is shown on a digital memory oscilloscope screen as a Lissajous figure. Fig. 6 shows 54.26 kHz (with a rotor). The vibration locus amplitude at the driving surfaces of converter decreases slightlythe vibration loci at the driving surfaces of converters with double slitted parts of 3.3 mm depth and 5 mm when the ultrasonic motor rotates. Fig. 6. Vibration loci at a driving part of a 15 mm diameter converter with and without a rotor part. 76 J. Tsujino et al. / Ultrasonics 38 (2000) 7276 6. Conclusion materials. The 15 mm diameter ultrasonic motor, together with a converter with double slitted parts, rotated at over 300 rpm.For increasing the available vibration velocity of the complex vibration converter, a new type of converter The converters with multiple slitted parts were found to be eVective for improving the vibration characteristicswith multiple slitted parts was studied. This converter has multiple slitted parts that are and increasing the available complex vibration velocity. installed in multiple positions, avoiding nodal positions along the converter for decreasing the maximum vibra- tion stress level at the vibration node part. The welding References characteristics of ultrasonic plastic welding using com- plex vibrations were studied. Also, 15 mm diameter 1 J. Tsujino, T. Ueoka, T. Shiraki, K. Hasegawa, R. Suzuki, M. ultrasonic motors using converters with double slitted Takeuchi, Proc. Int. Congress on Acoustics (1995) 447450. parts were tested. 2 J. Tsujino, Proc. IEEE 1995 Ultrasonics Symp., IEEE, New York, The longitudinal vibration nodal part was located 1996, pp. 10511060. between two slitted parts of the converters. The driving 3 J. Tsujino, T. Uchida, K. Yamano, T. Iwamoto, T. Ueoka, Proc. 2nd World Congress on Ultrasonics, Yokohama, Japan (1997)surface of the converter and the ultrasonic motor with 152153. double slitted parts vibrated at higher vibration velocities 4 J. Tsujino, T. Uchida, K. Yamano, T. Iwamoto, T. Ueoka, Proc. than those with a single slitted part at the same driv- IEEE 1997 Ultrasonics Symp., IEEE, New York, 1998, ing voltage. pp. 855860. The converter with double slitted parts significantly 5 J. Tsujino, T. Ueoka, Proc. IEEE 1999 Ultrasonics Symp., IEEE, New York, 1999, pp. 723728.improved the ultrasonic welding characteristics of plastic
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