Measurement, Scaling and Instrumentation (5 cpu) 3513058 Petri P. Kärenlampi
Lectures
24 h, exercises 60 h, literature and examinations 49 h
Measurement of volume, mass, and moisture content. Instrumentation
and signal processing. Spectroscopy, acoustics, thermography.
Calorimetry, polarized light.
Phase retardation, diffraction.
Student
will gain some knowledge regarding techniques and systems for measurement and
instrumentation, and consequently the ability to understand and sketch
principles for measurement applications.
Any
student is free to choose either to attend in the lecture room or follow a
livestream. However, there is a restriction of 13 students in the lecture room.
livestream
address:
http://www.uef.fi/live2
The
livestream is a one-way communication system. It needs to be complemented, to
allow questions and comments. There will be an e-mail connection during the
lectures. The lecturer is available during lectures at petri.karenlampi@gmail.com.
Regular uef-email of the lecturer is not reachable
from the lecture room.
If
you follow by livestream, please let the lecturer know that you are there.
Lectures:
BOR101, CA106
22.3.2021,
8-10 Volume, Mass
24.3.,
8-12 Moisture, Humidity, Sorption
29.3.,
8-10 Signal processing, Filtering, Integration
31.3., 8-12 Fourier-transform, Spectroscopy, Acoustics
12.4.,
8-10 Calorimetry
14.4.,
8-12 Thermography, Thermoelasticity
19.4., 8-10 Polarized light, Phase retardation
21.4., 8-12 Reporting of final exercise
-----
28.4.,
8-12 Discussion of last weekly exercise
Grading:
Weekly
exercises 25%
Exam
75%
There
are two types of exercises.
Weekly
exercises are due March 29, April 12, 19 and 26, at 9 am, to be returned to the
Lecturer’s green metallic mailbox by the Northern entrance of the Borealis
Building. Due to the pandemic, exercise reports also can be delivered to the
e-mail mentioned above. Emails sent after the due time will not be processed.
Weekly Exercises:
Final
Exercises.
Exercise consists of review of assigned literature, to be
selected from the list below. This review will be presented as an oral
presentation. No written report is required, provided the oral presentation is
satisfactory. However, the talk may have to be complemented in writing.
Please let the lecturer know whether you are available to give your
presentation in the lecture room by April 21.
Literature:
Willard, H.
H., Merritt, L. L., Dean, J. A. and Settle, F. A., Instrumental methods of
analysis. Wadsworth, Belmont, CA, 7th ed. 1988. 895 p. – pp. 1-39, 97-117,
761-785.
Young, H.
D. and Freedman, R. A., University Physics. Addison-Wesley, 10th Ed. 2000.,
pp. 593-619, 1053-1084.
Final examination April 30, at 8-10, Room F210.
Possibility for eventual renewals May 10, at 8-10, Room Bor101.
Measurement of wood chemical structure, and prediction
of its macroscopic properties, in terms of infrared spectroscopy.
4327. Brust, G., Infrared spectroscopy.
http://www.psrc.usm.edu/macrog/floor5.htm
4327b. Brust, G., Infrared vibrational modes.
http://www.psrc.usm.edu/macrog/irabs.htm
4573. Schimleck, L. R., Wright, P. J., Michell. A. J. and Wallis,
A. F., Near-infrared spectra and chemical compositions
of Eucalyptus globulus and E. nitens plantation
woods. Appita 50:40-46 (1997).
4394. Kindl, W., Schwanninger, M., Teischinger, A. and Hinterstoisser,
B., Relating chemical composition of wood to its mechanical properties: results
from UV-microscopic and near infrared microscopic studies. Fist International
Conference of the European Society of Wood Mechanics, April 19-21, 2001, Lausanne, Swizerland, pp. 15-19.
4395. Niemz, P., Körner, S., Wienhaus, O., Flamme, W. and Balmer, M., Orientierende
Untersuchungen sur Anwendung
der NIR-Spektroskopie für
die Beurteilung des Mischungsverhältnisses
Laubholz/Nadelholz und des Klebstoffanteils in Spangemischen.
(Applying NIR spectroscopy for evaluation of the hardwood softwood ratio and
resin content in chip mictures.) Holz
als Roh- und Werkstoff 50:25-28 (1992).
4270. Hauksson, J. B., Bergqvist, G., Bergsten, U., Sjöström, M. and Edlund, U.,
Prediction of basic wood properties for Norway Spruce. Interpretation of near infrared spectroscopy
data using partial least squares regression. Wood Sci. Tech. 35(6):475-485
(2001).
Wood pulp chemical structure, in terms of infrared spectroscopy.
4327. Brust, G., Infrared spectroscopy. http://www.psrc.usm.edu/macrog/floor5.htm
4327b. Brust, G., Infrared vibrational modes.
http://www.psrc.usm.edu/macrog/irabs.htm
4579. Åkerholm, M. and Salmén, L.,
Dynamic FTIR spectroscopy for carbohydrate analysis of wood pulps. J. Pulp
Paper Sci. 28(7):245-249 (2002).
4580. Backa, S. and Brolin, A., Determination of pulp
characteristics by diffuse reflectance FTIR. Tappi
74(5):218-226 (1991).
4581. Easty, D. B., Berben, S. A., DeThomas, F. A. and Brimmer, P. J., Near-infrared
spectroscopy for the analyisis of wood pulp:
quantifying hardwood-softwood mixtures and estimating lignin content. Tappi 73(10):257-261 (1990).
4582. Hsu, N. N.-C., Schroeck, J. J. and Errigo, L., Identification of the origins of stickies in deinked pulp. Tappi 80(4):63-68 (1997).
Mechanical properties of paper products, and control of
pulping and papermaking processes, in terms of infrared spectroscopy.
3829. Furumoto,
H., Lampe, U., Meixner, H. and Roth, C., Infrared
analysis for process control in the pulp and paper industry. Tappi 83(9) (2000). 9 p.
4586. Schultz, T. P. and Burns, D. A., Rapid secondary
analysis of lignocellulose: comparison of near infrared (NIR) and fourier transform infrared (FTIR). Tappi
73(5):209-212 (1990).
4583. Morrison, P. W. Jr., Cosgrove, J. E., Carangelo, R. M., Solomon, P. R., Leroueil,
P. and Thorn, P. A., Fourier transform infrared (FTIR) instrumentation for
monitoring recovery boilers. Tappi
74(12):68-78 (1991).
Properties
of pulps and cooking liquors properties in terms of ultraviolet spectroscopy.
4404. Ye C., Räty J., Nyblom I., Hyvärinen H-K. and Moss P., Estimation of lignin content in
single, intact pulp fibers by UV photometry and VIS
Mueller matrix polarimetry. Nordic Pulp & Paper Vol. 16, No. 2, p.
143-148 (2001).
4576. Evtuguin, D. V., Daniel, A. I. D. and Pascoal
Neto, C., Determination of hexeuronic acid and
residual lignin in pulps by UV spectroscopy in cadoxen
solutions. J. Pulp Paper Sci. 28(6):189-192 (2002).
4577.
Chai, X. S. , Li, J. and Zhu, J. Y., Simultaneous and
rapid analysis of hydroxide, sulphide and carbonate in kraft liquors by
attenuated total reflection UV spectroscopy. J. Pulp Paper Sci. 28(4):105-109
(2002).
Determination of wood structure, in terms of ultraviolet
spectroscopy.
1667. Scott, J. A. N, Procter, A.
R., Fergus, B. J. & Goring, D. A. I. The application of ultraviolet
microscopy to the distribution of lignin in wood. Description and validity of
the technique. Wood Sci. Tech. 3:73-92 (1969).
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Scott, J. A. N. & Goring, D. A. I. 1969. The distribution of lignin in sprucewood as determined by ultraviolet microscopy. Wood
Sci. Tech. 3(2):117-138.
1669. Fergus, B. J. and Goring, D.
A. I., The distribution of lignin in birch wood as determined by ultraviolet
microscopy. Holzforschung 24(4):118-124 (1970).
Microwaves in the determination of wood properties.
4288. Martin, P., Collet, R.,
Barthelemy, P. and Roussy, G., Evaluation of wood
characteristics: internal scanning of the material by microwaves. Wood Sci.
Tech. 21:361-371 (1987).
4598. Eskelinen, P. and Eskelinen, H., A K-band microwave measuring system for the
analysis of tree stems. Silva Fenn. 34(1):37-45 (2000).
4599. Montoro, T., Manrique, E. amd
González-Riviriego, A., Measurement of the refracting
index of wood microwave radiation. Holz als Roh- und Werkstoff
57:295-299 (1999).
Raman-spectroscopy in the determination of properties of
pulps and polymers.
4255. Galiotis,
C., A study of mechanisms of stress transfer in continuous- and
discontinuous-fiber model composites by laser raman
spectroscopy. Comp. Sci. Techn. 48:15-28 (1993).
3458. Hamad, W. Y. and Eichhorn, S.,
Deformation micromechanics of regenerated cellulose fibers using raman spectroscopy. J. Eng. Mat. Tech. 119:309-313 (1997).
2357. Hamad, W. and Eichhorn, S.,
Raman spectroscopic analysis of the microdeformation
in cellulosic fibers. 11th Fundamental Research Symposium, Cambridge, England,
Sept. 21-26, 1997, pp. 505-519.
4255. Galiotis,
C., A study of mechanisms of stress transfer in continuous- and
discontinuous-fiber model composites by laser raman
spectroscopy. Comp. Sci. Techn. 48:15-28 (1993).
Acoustics in the determination of the properties of sawlogs.
3941. Tsehaye, A., Bunchanan, A. H. and Walker, J. C. F., Sorting of logs
using acoustics. Wood Sci. Tech. 34(4):337-344 (2000).
4289. Han, W. and Birkeland, R., Ultrasonic scanning of logs. Industrial Metrology 2:253-281 (1992).
4839. Huang, C.-L., Lindström, H., Nakada, R., and Ralston, J., Cell wall structure and wood properties determined by acoustics – a selective review. Holz als Roh- und Werkstoff 61:321-335 (2003).
Applications of mechanical wave detection in wood and paper industries.
4313. Kang, H. and Booker, R. E., Variation of stress
wave velocity with MC and temperature. Wood Sci. Tech. 36(1):41-54 (2002).
2254. Craver,
J. K. and Taylor, D. L., Nondestructive sonic measurement of paper elasticity. Tappi 48(3):142-147 (1965).
4596. Sasaki, Y., and Hasegawa, M., Ultrasonic
measurement of applied stresses in wood by acoustoelastic birefringent method.
12th International Symposium on Nonderstructive
Testing of Wood, Sopron, Hungary, September 2000,
http://www.ndt.net/article/v06n03/sasaki/sasaki.htm
1186. Batten,
G. L., The differences between sonically and mechanically determined elastic
moduli of paper. In: Caulfield, D. F., Passaretti, J.
D. and Sobczynski, S. F. (eds.), "Materials
Interactions Relevant to the Pulp and Paper and Wood Industries", Vol.
197, pp. 163-172. Materials Research Society, Pittsburg, 1990.
Monitoring fractures through acoustic emissons.
1196. Yamauchi, T. and Murakami, K., Acoustic and
optical measurements during the straining of paper. 1991 International Paper Physics Conference,
September 22-26, Kona, Hawaiji , pp. 681-684.
3815.
Berg, J.-E. and Gradin, P. Effect of temperature on
fracture of spruce in compression, investigated by use of acoustic emission
monitoring. J. Pulp Paper Sci. 26(8):294-299 (2000).
4108. Aicher, S., Höfflin, L. amd Dill-Langer, G., Damage evolution and acoustic emission
of wood at tension perpendicular to fiber. Holz als Roh-
und Werkstoff 59:104-116 (2001).
4099b.
Landis, N. E. and Whittaker, D. B., Acoustic emission as a measure of wood
fracture energy. Fist International Conference of the European Society of Wood Mechanics,
Changes in cell wall structure during drying.
4034. Thuvander, F., Wallström, L.,
Berglund, L. A. and Lindberg, K. A. H., Effects of an impregnation procedure
for prevention of wood cell wall damage due to drying. Wood Sci. Tech.
34(6):473-480 (2001).
4401. Wallström, L., and Lindberg, K. A. H., Distribution of added chemicals in the cell of high temperature dried
and green wood of swedish pine, Pinus sylvestris.
Wood Sci. Tech. 34(4):327-336 (2000).
826. Van den Akker, J. A.: Some theoretical considerations on the mechanical properties of fibrous structures. In: Bolam, F.(ed.), Formation and structure of paper Vol I. Transactions of the symposium held at Oxford, September 1961. Technical Section of the British Paper and Board Makers' Association, London 1962, pp. 205-241.
Freezing of water in wood and pulp.
4361.
Nakamura, K., Hatakeyama, T., and Hatakeyama,
H., Studies on bound water of cellulose by differential scanning calorimetry.
Text. Res. J. 51(9):607-613 (1981).
3531.
Maloney, T. and Paulapuro, H., The formation of pores
in the cell wall. J. Pulp Paper Sci. 25(12):430-436 (1999).
Thermography applications.
1940.
Tanaka, A., Otsuka, Y. and Yamauchi, T., In-plane fracture toughness testing of
paper using thermography. Tappi 80(5):222-226 (1997).
2165. Kiiskinen, H. T., Kukkonen, H.
K., Pakarinen, P. I. And Laine, A. J., Infrared
thermography examination of paper structure. Tappi
80(4):159-162 (1997).
4087.
Hojjatie, B., Abedi, J. and Coffin, D. W.,
Quantitative determination of in-plane moisture distribution in paper by
infrared thermography. Tappi 84(5) (2001). 11 p.
4589. Maggard, J., On-line measurement of dryer
performance. Tappi 78(3):264-265 (1995).
4590. Tanaka, T. and Divós,
F., Wood inspection by thermography. 12th International Symposium on Nonderstructive Testing of Wood, Sopron, Hungary, September
2000, http://www.ndt.net/article/v06n03/tanaka/tanaka.htm.
4597. Wyckhuyse, A. and Maldague, X., A study of wood inspection by infrared
thermography, Parti I: wood pole inspection by
infrared thermography. Res. Nonderstr. Eval.
2001:1-12.
1670. Scott, J. A. N. and Goring, D.
A. I., Photolysis of wood microsections in the ultraviolet microscope. Wood
Sci. Tech 4:237-239 (1970).
Cell wall structure through birefringence.
1467. Manwiller,
F. G., Senarmont compensation for determining fibril
angles of cell wall layers. For. Prod. J. 16(10):26-30 (1966).
1090. Page, D.
H. and El-Hosseiny, F. The birefringerence
of wood pulp fibers and the thickness of the S1 and S2 layers. Wood and Fiber
6(3):186-192 (1974).
1086. Crosby,
C. M., De Zeeuw, C. and Marton,
R., Fibrillar
angle variation in red pine determined by Senarmont compensation.
Wood Sci. Tech. 6:185-195 (1972).
1470. Preston, R. D., The fine
structure of the walls of the conifer tracheid.
II. Optical properties of dissected walls in Pinus insignis. Proc. R.
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Microfibril angle through polarized light.
1081. Page, D. H., A method for determining fibrillar
angle of wood tracheids. J. Micros. 90(2):137-143
(1969).
1089. Leney, L., A technique for measuring fibril angle using
polarized light. Wood Fiber 13(1):13-16 (1981).
4603. El-Hosseiny, F. and Page, D. H., The measurement of fibril
angle of wood fibres using polarized light. Wood and
Fiber 5(3):208-214 (1973).
Microfibril angle through x-ray interference.
1464. Cave, I. D., Theory of X-ray
measurement of microfibril angle in wood. For. Prod. J. 16(10):37-42 (1966).
1468. Meylan,
B. A., Measurement of microfibril angle by X-ray diffraction. For. Prod. J.
17(5):51-58 (1967).
1105. Prud'homme,
R. E. and Noah, J., Determination of fibril angle distribution in wood fibers:
a comparison between thex-ray diffraction and the
polarized microscope methods. Wood Fiber 6(4):282-289 (1975).
4858. Andersson, S., Serimaa, R., Torkkeli, M., Paakkari, T., Saranpää, P. and Pesonen, E., Microfibril angle of Norway spruce [Picea abiues (L.) Karst.]
compression wood: comparison of measuring techniques. J. Wood Sci. 46:343-349
(2000).
X-ray densitometry.
4600. Gureyev,
T. E. and Evans, R., A method for measuring vessel-free density distribution in
hardwoods. Wood Sci. Tech. 33:31-42 (1999).
4601. Stanzl-Tschegg,
S. E., Filion, L., Tschegg,
E. K. and Reiterer, A., Strength properties and
density of SO2 polluted spruce wood. Holz als Roh- und Verkstoff
57:121-128 (1999).
4602.
Divos, F., Szegedi, S. and Raics,
P., Local densitometry of wood by gamma back-scattering. Holz
als Roh- und Verkstoff. 54:279-281 (1996).
4240.
Bergsten, U., Lindeberg, J., Rindby,
A. and Evans, R., Bach measurements of wood density of intact or prepared drill
cores using x-ray microdensitometry. Wood Sci. Tech.
35(5):435-452 (2001).
Internal structure of sawlogs through x-ray radiation.
3628. Grundberg, S., X-ray
log scanner - a tool for control of the sawmill process. Luleå
Univ. of Technology, Div. of Wood Technology, Skellefteå,
SE, Report 1999:37.
3629. Oja, J., X-ray measurement of properties of saw logs. Luleå Univ. of Technology, Div. of Wood Technology, Skellefteå, SE, Report 1999:14.
4857. Skog, J. and Oja, J., Improved log sorting combining X-ray and 3D scanning – a preliminary study. Cost E 53 Conference – Quality Control for Wood and Wood Products, October 2007, Warsaw, Poland, 133-140.
Wood density through transmission intensity of visible.
3992. Palviainen, J. and Silvennoinen, R., Inspection of wood density by
spectrophotometry and diffractive optical element based
sensor. Meas. Sci. Tech. 12:1-8 (2001).
4413. Palviainen, J., Sorjonen, M., Silvennoinen, R.
and Peiponen, K.-E., Optical sensing of colour print
on paper by a diffractive optical element. Meas. Sci. Tech. 13:N31-37
(2002).
Anisotropy through light scattering patters.
4414. Simonaho, S.-P., Palviainen, J., Tolonen, Y. and Silvennoinen, R., Determination of wood grain direction
from laser light scattering pattern. Optics and Lasers in Engineering 41(1):95-103 (2004).
3992. Palviainen, J. and Silvennoinen, R., Inspection of wood density by
spectrophotometry and diffractive optical element based
sensor. Meas. Sci. Tech.
12:1-8 (2001).
4413. Palviainen, J., Sorjonen, M., Silvennoinen, R.
and Peiponen, K.-E., Optical sensing of colour print
on paper by a diffractive optical element. Meas. Sci. Tech. 13:N31-37
(2002).
Nuclear magnetic resonance in identification and characterization of water.
4592. Guzenda, R. and Wieslaw, O., Identification of free and bound water content
in wood by means of NMR relaxometry. 12th International Symposium on Nonderstructive Testing of Wood, Sopron, Hungary, September
2000, http://www.ndt.net/article/v06n03/guzenda/guzenda.htm
4287. Chang, S. J., Olson, J. R. and Wang, P. C.,
NMR imaging of internal features in wood. For. Prod. J. 39(6):43-49 (1989).
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D., Blicharsca, B., Focher,
B. and Capretti, G., 1H NMR relaxation study of paper as a system of cellulose
and water. Tappi 79(6):113-122 (1996).
Heartwood detection for Scotch pine by fluorescence image analysis
5166. Antikainen Jukka, Hirvonen Tapani, Kinnunen Jussi, Hauta-Kasari Markku. Heartwood detection for Scotch pine by fluorescence image analysis. Holzforschung, Vol. 66, pp. 877–881, 2012.