Wpływ zmniejszania się mimośrodu na ugięcia prętów mimośrodowo ściskanych
The influence of decreasing eccentricity on the deflections of a bar subjected to eccentric compression
In all investigations concerning the computation of finite deflections of eccentrically compressed bars it has been assumed hitherto that the eccentricity of the force remains constant («normal to the force», Fig. la) during the deformation process. In addition to this type of load, which can be realized, for instance, in the somewhat unusual way shown at Fig. 2 or, more .commonly, with the axial force and the moment acting independently (the values' increasing proportionally), various other types of eccentric load are possible. Above all, there is the case shown at Fig. 1b, where the bar representing the eccentricity remains always normal to the tangent to the loaded bar («the decreasing eccentricity»).
The object of this paper is to compare the deflections for the two types of load. In particular, since the analysis for constant eccentricity is simpler, and the decreasing eccentricity seems to be more often encountered in practice, the differences (absolute and relative) between these two cases are investigated. The cases in which these differences can be disregarded are indicated.
The notations used are those of the previous paper, [18], by the present author. Using the exact equation of the deflection curve (2.1), the Eqs. (2.20) are obtained for the maximum deflection in the case of decreasing eccentricity and (2.21) in the case of constant eccentricity. These are equations of the type f(ϑ, Θ, m) = 0 , the unknown being ϑ = δ/l, where l denotes the length of the bar and Θ, and m the dimensionless eccentricity and dimensionless axial force, respectively.
In Art. 3 these equations are expressed in a parametric form which makes possible a computation of the sets of variables ϑ, Θ and m, corresponding each other. Further calculations are performed graphically and numerically. Thus, the diagram of the curve Θ = const in the ϑ m plane is constructed (Fig. 3), together with the diagram of the curve ϑ = const in the plane Θ m (Fig. 4). On the basis of Fig. 4, are drawn diagrams of the absolute and relative (percentage) deflection differences between the two types of load (Figs. 5 and 6).
In conclusion, it can be assumed that the differences between the two types of load can be disregarded when the eccentricity of the force is of the order of a thousandth part of the bar length.
A four-figure table of deflections of a bar under buckling (axial compression), calculated from the accurate equation (4.7), is presented too. This case can be treated as the limit case for the problem under consideration, the difference between the two types of load being zero.
References
M. E. Bierrnan, O prodolnoj ustojcziwosti stierżniej, Sborn. stat. Rasczety na procznost', żesłkost', ustojcziwost' i kołebanja, Moskwa 1955, s. 216–222.
H. Czopowski, Kilka słów o wyboczeniu sprężystym. Czasop. Techn. 7 (1924).
B. G. Galerkin, Sobranje soczinienij, t. 1, wyd. AN ZSSR, Moskwa 1952, s. 125-154.
F. S. Jasiński, Izbrannyje raboty po ustojcziwosti sżatych stierżniej, Gostdechizdat, Moskwa-Leningrad 1952.
S. D. Lejties, Ustojcziwost' sżatych stalnych stierżniej, Gos. Izd. Lit, po Stroit. i Archit., Moskwa 1954.
J. Mutermilch, ścisły wzór na krzywiznę w zastosowaniu do mimośrod¬kowego ściskania, Arch. Mech. Stos. .1 (1949), 3, Gdańsk 1949, s. 203-228.
J. Mutermilch, Zastosowanie rachunku różnicowego do obliczeń opar¬tych na ścisłym równamiu odkształconej, z. 3/1 mat. nadesł. na Zjazd Nauk PZITB w Gdańsku, 1949.
J. Naleszkiewicz, Zagadnienia stateczności sprężystej, Wyd. Kom., Warszawa 1953.
E. P. Popow, Nieliniejnyje zadaczi statiki tonkich stierżniej, Gostiechizdał, Moskwa-Leningrad 1948.
T. Pöschl, Ober eine Methode zur angendherten Lósung nichtlinearer Differentialgleichungen mit anwendung auf die Berechnung der Durchbiegung bei der Knickung gerader Stdbe, Ing.-Archiv 9 (1938), 1, s. 34–41.
I. M. Ryżiki, I. S. Gradsztiejn. Tablicy intiegrałow, summ, riadow i proizwiedienij, Gostiechizdat, Moskwa-Leningrad 1951.
B. I. Siegał, K. A. Siemiendiajew, Piatiznacznyje matiematiczeskie tablicy, wyd. AN ZSSR, Moskwa-Leningrad 1950.
R. V. Southwell, An Introduction to the Theory of Elasticity, przekł. ros., IL, Moskwa 1948.
F. Szelągowski, Wpływ siły krytycznej na stateczność prętów zginanych lub ściskanych, mimośrodkowo, Przegl. Techn. Warszawa 1927.
G. Wästluild, Sven G. Bergström, Tests with Compressed Steel Members and General Principles for Standard Specifications, Cz. 4 mat. nadesł. na VI Zjazd Nauk. PZITB w Gdańsku, 1–4, XII, 1949.
W. Wierzbicki, O powstawaniu zjawiska wyboczenia, Przegl, Techn. 71 (1932), 31/32 i 35/36, s. 341–345 i 387–391.
W. Wierzbicki, O powstawaniu wyboczenia prętów prostych, Rozpr Inż. XII, Warszawa 1954.
M. Życzkowski, Ugięcie pręta ściskanego mimośrodowo pod działaniem siły krytycznej, Rozpr. Inż. IV, Warszawa 1953.
M. Życzkowski, Tablice funkcyj Eulera i pokrewnych, PWN, Warszawa 1954.