Abstracts
A model for the normal stress distribution of the Great Pyramid is presented. The model is sufficiently simple as to be discussed at a basic university physics level
Keywords:
statics; mechanical equilibrium
Um modelo para a distribuição das tensões normais da Grande Pirâmide de Gizé é apresentado. O modelo é simples e pode ser discutido no ensino de física geral nos cursos básicos universtários.
Palavras-chave:
estática; equilíbrio mecânico
The Great Pyramid of Gizeh, also known as Khufu's Pyramid or Cheops' Pyramid was built between 2560 b.C.E. and 2040 b.C.E. as a tomb for pharaoh Khufu of the IV dinasty. The original dimensions were a height of meters and a square base whose side was meters [1[1] M. Lehner, The Complete Pyramids of Egypt (Thames and Hudson, New York, 1997).,2[2] M. Seidel e R. Schulz, Egito - Coleção Arte e Arquitetura (Dinalivro, Lisboa, 2006).]. The two mortuary rooms, the gallery, and the ascending and descending passages correspond to small fraction of the total volume and this allow us to consider the Great Pyramid as an enormous block of solid rock with a mean density approximately equal to kg/m. Several details concerning its construction can be found in [3[3] A.C. Tort, Physics Education 50, 516 (2015).] and references therein. The Great Pyramid give us the chance of introducing a simple quantitative model for the behavior of its normal stresses that we can discuss with our students at a moderate level of difficulty as we shall see in what comes next.
For simplicity let us suppose that this normal stress field that we shall denote by and measure it in , is a function of only, that is . At the base, the force associated with this stress field must balance the total weight of the pyramid and at the vertex it must be null.
Suppose that the pyramid is divided into infinitesimal truncated pyramids. Consider an element whose mass is , where is the mean density and is the the area of the cross section at . In equilibrium, see Figure 1
Writing , and , and substituting into equation (1) we obtain up to first order
The formal solution of this differential equation for uniform and is
where is an integration constant. Making use of a theorem from the measure theory of volumes of cones and pyramids [4[4] E. Moise, Elementary Geometry from an Advanced Standpoint (Addison-Wesley, Reading, 1963).] we writeTaking equation (4) into equation (3) we have
Defining
and integrating we obtainThe upwards force that the ground exerts on the pyramid must balance the weight of the latter, this means that for we must have
Since for , , from equation (7) it follows that , and the normal stress as a function of reads
Notice that for , is null as it should. The strength of the vertical force at the base level is equal to N, that is, approximately tonnes! This force balances the total weight of the Great Pyramid. In Figure 2, we show the graphs of the rescaled normal stress and of the rescaled cross section as functions of . Notice that is proportional to , and , is proportional to , but the the upwards force is proportional to .
With the equations that we have at our disposal we can easily verify that a good portion of the total weight of a pyramid is kept in mechanical equilibrium by the truncated pyramid whose base is and whose height can be much less than its maximum height .
The weight of the pyramid as a function of its height is given by
Setting as before we have
Evaluating the integral we obtain
For a given , the weight of the portion of the pyramid above is
The weight of the portion of the pyramid above must be balanced by the vertical upward force associated with the normal stress at , . Making use of equation (9) we can easily verify that .
Suppose that , that is, equal to height of the c. of m. of the pyramid. In this case, from equation (9) we see that the normal stress is
The cross section at is equal to , hence the strength of the balancing force acting on the upper part of the pyramid () is
that is, equal to almost half of the total weight of the Great Pyramid. This force can be considered as applied to the center of mass of upper part which lies at the height from the bottom, see Figure 3. Also, at , the mass of the upper part is equal to of the total mass of the pyramid, , and that of the lower part equal to , as can be easily verified with the help of the equations for and . The choice of the pyramidal shape, (or conical) means that most of the weight will be counterbalanced by the inferior layers of the structure, see the graph shown in Figure 4.The vertical upward force associated to the tensile stress field and the weight of the upper part of the pyramid, that is, are shown here for . The point is the center of mass of the upper portion of the pyramid.
The approach employed here can be easily extended to other pyramidal or conical shapes or even truncated pyramids as those that can be found in Central America.
References
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[1]M. Lehner, The Complete Pyramids of Egypt (Thames and Hudson, New York, 1997).
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[2]M. Seidel e R. Schulz, Egito - Coleção Arte e Arquitetura (Dinalivro, Lisboa, 2006).
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[3]A.C. Tort, Physics Education 50, 516 (2015).
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[4]E. Moise, Elementary Geometry from an Advanced Standpoint (Addison-Wesley, Reading, 1963).
Publication Dates
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Publication in this collection
Dec 2016
History
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Received
08 Apr 2016 -
Reviewed
10 May 2016 -
Accepted
15 May 2016