Forest Products Mechanics (6 Ects / 4ov)
3513055
Puutuotteiden mekaniikka
Petri P.
Kärenlampi
Lectures 26 h,
Exercises 74 h, literature and examinations 60 h
Essentials: Strain. Stress. Stress-strain
relations. Transformations. Time-dependent mechanical behavior. Moisture and
temperature effects.
Complementary
knowledge:
Irrecoverable deformations. Energy dissipation. The fracture energy.
Special
knowledge:
Brittleness. Strain-softening.
Student
will gain ability to analyze, evaluate and develop mechanical behavior of
structures, in particular those made of porous, anisotropic, hygroscopic and
time-dependent materials.
Lectures 26 hours:
Room N100
8.9. 2025 8-10 Normal Strain
Normal Stress
Stress-Strain Relations
10.9. 8-12 Volumetric Strain
Shear Strain
Shear Stress
Multiaxial Stress and Strain States
Off-Axis Stress and Strain
Stress and Strain Transformations
15.9. 8-10 Time-Dependent Mechanical Behavior
16.9. 14-18 Moisture and Temperature Effects
Time-Temperature-Moisture-Specific Volume –
Equivalency
22.9. 8-10 Irrecoverable Deformations
23.9. 12-16 Yield Criterion
29.9. 8-10 Strength of Materials The Fracture Energy
30.9. 8-12 Brittleness and Strain-Softening
8.10. 8-10 N100 10-12 N101
Wood Products Applications
Pulping Applications Paper and Paperboard Applications
Lectures will be given at N100, and streamed with
Video Conference Apparatus. Presently, there are no restrictions to presence in
the lecture room. Any participant shall have an opportunity to present
questions and comments either in the lecture room or within a Teams-meeting.
Exam will be on site. Please check the exam dates
proposed below. Let the lecturer know if there is any time conflict.
Lectures on Mondays can be joined at
Lectures on Tuesdays can be joined at
Lectures on Wednesdays can be joined at
Grading:
Weekly
exercises 25%
Exam 75%
There are three
types of exercises.
Firstly, there
are weekly exercises. Then, there is an experimental exercise. And finally,
there is a project exercise, where each student presents a forest products
application of Mechanics.
Weekly exercises are due each Monday at 9 am, between September 15 and
October 6, to be returned to the green metallic mailbox by the main entrance of the Borealis Building.
Experimental exercise October
03. Gathering at Metla-house lobby 13:30 (Yliopistokatu 6).
Reporting Sessions for
Experimental exercise on October 8 (N 101) at 10-12.
Project exercise
September-October.
Course Literature:
Tsai, S. W. and Hahn, H. T., Introduction to composite materials.
Technomic Publishing Co.,
Simo, J. C. and Hughes, T. J. R., Computational inelasticity.
Interdisciplinary applied mathematics, Springer Verlag 1998, pp. 1-70.
Smith, T. L., Stress-strain-time-temperature relationship for polymers.
ASTM Materials Sci. Series 3, STP-325. American Society of Testing and
Materials,
Final examination October 10, at
10-12, Bor 100.
Possibility for eventual
renewals October 24 at 10-12, Bor 100.
Exercises
Contents:
There are three
types of exercises:
1.Weekly
exercises
As explained
above. The approximated time consumption is 37 hours.
Lecture recordings
https://uef.cloud.panopto.eu/Panopto/Pages/Viewer.aspx?id=a8664543-c257-4f7a-9e04-b34c00a835b5
https://uef.cloud.panopto.eu/Panopto/Pages/Viewer.aspx?id=64616faf-1fe7-4765-97fd-b34c00a9d110
https://uef.cloud.panopto.eu/Panopto/Pages/Viewer.aspx?id=7fadded6-fb09-4ba8-baf2-b07c00ab555c
https://uef.cloud.panopto.eu/Panopto/Pages/Viewer.aspx?id=1cc2f6cd-7c06-43fd-a202-b07c00ab5524
https://uef.cloud.panopto.eu/Panopto/Pages/Viewer.aspx?id=8350b0ec-685e-4b83-827e-b084005a9880
https://uef.cloud.panopto.eu/Panopto/Pages/Viewer.aspx?id=9420828d-4ad9-4930-b0ca-b084005a985e
https://uef.cloud.panopto.eu/Panopto/Pages/Viewer.aspx?id=79489194-13bf-4a7b-9134-b09a00b6b382
https://uef.cloud.panopto.eu/Panopto/Pages/Viewer.aspx?id=2bfe26c6-b0a1-4dd1-8f00-b08c005a213f
https://uef.cloud.panopto.eu/Panopto/Pages/Viewer.aspx?id=80bf3922-2adc-479d-8418-b09200d85944
https://uef.cloud.panopto.eu/Panopto/Pages/Viewer.aspx?id=62f19d12-e3b6-402c-9578-b09200d8591b
https://uef.cloud.panopto.eu/Panopto/Pages/Viewer.aspx?id=8df6d0af-c481-44ad-a2ce-b09200d858ea
https://uef.cloud.panopto.eu/Panopto/Pages/Viewer.aspx?id=4b47ab17-80a8-4c22-8934-b34c00ae205e
https://uef.cloud.panopto.eu/Panopto/Pages/Viewer.aspx?id=be1ad0d6-e8cd-4167-8788-b34c00aac976
2.
Implementation and analysis of mechanical experiments
The approximated time consumption of
this exercise is 24 hours, of which 2 hours in implementation of the
experiment, and 22 hours for analyzing the results.
Briefly, the exercises contain
Experimental determination of:
Small-Strain Stiffness
Stress-Strain Curve
Tangential Stiffness
Irrecoverable Strain
Thermal expansion
Large-Strain Stiffness
Energy Dissipation
The effect of the following factors
on the characteristics above
will be investigated:
Moisture Content
Straining Rate
3. Presentation of an application of
mechanics in the
The approximated time consumption of
this exercise is 13 hours, which is budgeted for the study of an application,
on the basis of literature, and the preparation of a presentation regarding it.
The presentations (each of duration 20...30 minutes, followed by discussion)
will be given during the three last sessions of the lecture program.
Any presentation of application is
supposed to based in documents identified by the instructor. The title of the
presentation is to be designed by the presenter. The following literature is to
be used as a basis of presentations. Any participant may choose one of the
following groups of references:
A/
3211.
Brebner, K. I., Schneider, M. H. and St-Pierre, L. E., Flexural strength of
polymer-impregnated eastern white pine. For. Prod. J. 35(2):22-27 (1985).
3210.
Brebner, K. I., Schneider, M. H. and Jones, R. T., The influence of moisture
content on the flexural strength of styrene-polymerized wood. For. Prod. J.
38(4):55-58 (1988).
3217.
Schneider, M. H., Phillips, J. G., Tingley, D. A. and Brebner, K. I.,
Mechanical properties of polymer-impregnated sugar maple. For. Prod. J.
40(1):37-41 (1990).
3215.
Schneider, M. H., Brebner, K. I. and Hartley,
B/
3845.
English, B. W. and Falk, R. H., Factors that affect the application of
woodfiber-plastic composites. In Proceedings: "Woodfiber-plastic
composites: virgin and recycled wood fiber and polymers for composites",
May 1-3, 1995, Madison, Wisc., pp. 189-194. Forest Products Society,
3852.
Kortschot, M. T., Engineering design and materials seclection: principles and
applications for woodfiber-polymer composites. Fourth International Conference
on Woodfiber-Plastic Composites, May 12-14, 1997,
3835.
Simonsen, J., The mechanical properties of woodfiber-plastic composites:
theoretical vs. experimental. In Proceedings: "Woodfiber-plastic
composites: virgin and recycled wood fiber and polymers for composites",
May 1-3, 1995, Madison, Wisc., pp. 47-55. Forest Products Society,
3854.
Maiti, S. N., Wood flour-polypropylene composites: structure-property
relationships. Fourth International Conference on Woodfiber-Plastic Composites,
May 12-14, 1997,
3866.
Selke, S. E. and Childress, J., Wood fiber/high-density polyethylene
composites: ability of additives to enhance mechanical properties.
In:"Wood-Fiber/Polymer Composites: Fundamental Concepts, Processes, and
Material Options", Ed. M. P. Wolcott. Forest Products Society,
4495. Stamm, A. J., Burr, H. K. and Kline, A.
A., Staybwood – a heat stabilized wood.
4498. Stamm, A.
J.,Thermal degradation of wood and cellulose.
4499. Stamm, A. J. and Baechler, R. H., Decay
resistance and dimensional stability of five modified woods.
4496. Hillis, W. E., High temperature and
chemical effects on wood stability. Wood Sci. Tech.18:281-293 (1984).
4487.
4315. Kamdem, D. P., Pizzi, A. and Jermannaud,
A., Durability of heat-treated wood. Holz als Roh- un Werkstoff 60(1):1-6
(2002).
4489. Thermowood. Finnish thermowood
association.
http://www.thermowood.fi/pdf/thermowood_english.pdf
E/
4490. Inoue,
M., Norimoto, M., Tanahashi, M. and Rowell, R. M., Steam of heat fixation of
compressed wood. Wood Fiber Sci. 25:224-235 (1993).
4491.
Ito, Y., Tanahashi, M., Shigematsu, M., Shinoda, Y. and C. Ohta, C., Compressive-Molding of wood by
high-pressure steam-treatment: Part 1. Development of compressively molded
squares from thinnings. Holzforschung 52:211-216 (1998).
4492.
Ito, Y., Tanahashi, M., Shigematsu, M. and Shinoda, Y., Compressive-molding of
wood by high-pressure steam-treatment: Part 2. Mechanism of permanent
fixation. Holzforschung 52:217-221
(1998).
4103.
Tanahashi, M., Kyomori, K., Shigematsu, M. and Onwona-Agyeman, S., Development
of compressive molding process of wood by high-pressure steam and mechanism of
permanent fixation for transformed shape. Fist International Conference of the
European Society of Wood Mechanics,
April 19-21, 2001,
4104.
Heger, F., Girardet, F., Moeckli, P. and Navi, P., Thermo-hydro-mechanical
demsification and influence of post-treatment on set-recovery. Fist
International Conference of the European Society of Wood Mechanics, April 19-21, 2001,
4466. Wallström, L., Lindberg, K. A.
H. and Johansson,
4467. Wallström, L., and Lindberg, K.
A. H., Wood surface stabilization with polyethylene glycol, PEG. Wood Sci.
Tech. 29:109-119 (1995).
4465. Wallström, L., and Lindberg, K.
A. H., Measurement of cell wall penetration in wood of water-based chemicals
using SEM/EDS and STEM/I. Wood Sci. Tech. 33(2):111-122 (1999).
G/
4386. Kifetew, G.,Thuvander, F., Berglund, L.
A. and Lindberg, H., The effect of drying on wood fracture surfaces from
specimens tested in wet condition, Wood Sci. Tech. 32(2):83-94 (1998).
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).
H/
3512. Björkqvist, T., Menetelmä ja
laite puun mekaaniseksi kuiduttamiseksi. Förfarande och anordning för mekanisk defibrering av trä. Finnish Patent 98148 (1995). WO9638624: Method and apparatus for
mechanical defibration of wood, published 1996-12-05.
4230. Björkqvist, T. and Lucander, M., Grinding
surface with an energy-efficient profile. 2001 International Mechanical Pulping
Conference, Helsinki, Finland, June 4-8, 2001, pp. 373-380.
I/
4473. Kärenlampi,
P. P., Tynjälä, P. and Ström, P.: Molecular fatigue in cell walls. 2002 Paper
Physics Seminar, Finger Lakes, NY, Sept. 8-13, pp. 240-243
4377. Kärenlampi, P. P.,
Tynjälä, P. and Ström, P., Molecular reorganization in wood. Mechanics of
Materials 35(12):1149-1159
(2003).
4322. Kärenlampi, P. P., Tynjälä, P. and
Ström, P., Molecular fatigue in steamed wood. Int. J. Fatigue 25(6):489-497
(2003).
4249. Kärenlampi, P. P., Tynjälä, P. and
Ström, P., Off-axis fatigue loading of steamed wood. Int. J. Fatigue
24(12):1235-1242 (2002).
J/
2623. Östlund, S., Niskanen, K. and
Kärenlampi, P., On the prediction of the strength of paper structures with a
flaw. J. Pulp Paper Sci. 25(10):353-360 (1999).
K/
3579.
Östlund, S. and Kärenlampi, P., Structural geometry effect on the size-scaling
of strength. Int. J. Fract. 109(2):141-151 (2001).
L/
2661.
Tryding, J. and Gustafsson, P. J., Characterisation of tensile fracture
properties of paper. Tappi 83(2):84-89 (2000).
3622.
Tryding, J. and Gustafsson, P. J., Analysis of notched newsprint sheet in mode
I fracture. J. Pulp Paper Sci. 27(3):103-109 (2001).
M/
3342. Uesaka, T. and Ferahi, M., Principal factors
controlling press room breaks. 1999 Paper Physics Conference,
4486. Uesaka, T., Ferahi, M., Hristopulos, D.,
Deng, N. and Moss, C., Factors controlling press room runnability of paper .
12th Fundamental Research Symposium,
4452. Hristopoulos, D. T. and Uesaka,
T., Model of machine-direction web dynamics and impact on web brake rates.
PPP2002, Progress in Paper Physics Seminar, Finger Lakes /
N/
3362. Wahlström, T., Adolfsson, K., Östlund, S. and
Fellers, C., Numerical modeling of the cross direction shrinkage profile in a
dryer section. A first approach. 1999 Paper Physics Conference,
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2976.
Glynn, P., Jones, H. W. H. and Gallay, W., The fundamentals of curl in paper.
Pulp Paper
2973. Gray, D. G., Chirality and curl in paper sheets.
J. Pulp Paper Sci. 15(3):J105-109 (1989).
4458. Östlund, M., Östlund, Ö., Carlsson,
L. A. and Fellers, C., Experimental determination of residual stresses in
paperboard. PPP2002, Progress in Paper Physics Seminar, Finger Lakes /
Syracuse, NY, Sept. 8-13, 2002, pp. 180-183..
4443. Persson, M. and Wahlström, T.,
The development of moisture gradients using different stategies and their
influence on process-induced curl. PPP2002, Progress in Paper Physics Seminar,
Finger Lakes /
P/
4841.
Stanzl-Tschegg, S. E., Microstructure and fracture mechanical response of wood.
Int. J. Fract. 139:495-508 (2006).