Contact mechanics is the study of the deformation of solids that touch each other at one or more points.[1] [2] A central distinction in contact mechanics is between stresses acting perpendicular to the contacting bodies' surfaces (known as normal stress) and frictional stresses acting tangentially between the surfaces (shear stress). Normal contact mechanics or frictionless contact mechanics focuses on normal stresses caused by applied normal forces and by the adhesion present on surfaces in close contact, even if they are clean and dry.Frictional contact mechanics emphasizes the effect of friction forces.
Contact mechanics is part of mechanical engineering. The physical and mathematical formulation of the subject is built upon the mechanics of materials and continuum mechanics and focuses on computations involving elastic, viscoelastic, and plastic bodies in static or dynamic contact. Contact mechanics provides necessary information for the safe and energy efficient design of technical systems and for the study of tribology, contact stiffness, electrical contact resistance and indentation hardness. Principles of contacts mechanics are implemented towards applications such as locomotive wheel-rail contact, coupling devices, braking systems, tires, bearings, combustion engines, mechanical linkages, gasket seals, metalworking, metal forming, ultrasonic welding, electrical contacts, and many others. Current challenges faced in the field may include stress analysis of contact and coupling members and the influence of lubrication and material design on friction and wear. Applications of contact mechanics further extend into the micro- and nanotechnological realm.
The original work in contact mechanics dates back to 1881 with the publication of the paper "On the contact of elastic solids"[3] ("Über die Berührung fester elastischer Körper") by Heinrich Hertz. Hertz was attempting to understand how the optical properties of multiple, stacked lenses might change with the force holding them together. Hertzian contact stress refers to the localized stresses that develop as two curved surfaces come in contact and deform slightly under the imposed loads. This amount of deformation is dependent on the modulus of elasticity of the material in contact. It gives the contact stress as a function of the normal contact force, the radii of curvature of both bodies and the modulus of elasticity of both bodies. Hertzian contact stress forms the foundation for the equations for load bearing capabilities and fatigue life in bearings, gears, and any other bodies where two surfaces are in contact.
Classical contact mechanics is most notably associated with Heinrich Hertz.[4] In 1882, Hertz solved the contact problem of two elastic bodies with curved surfaces. This still-relevant classical solution provides a foundation for modern problems in contact mechanics. For example, in mechanical engineering and tribology, Hertzian contact stress is a description of the stress within mating parts. The Hertzian contact stress usually refers to the stress close to the area of contact between two spheres of different radii.
It was not until nearly one hundred years later that Johnson, Kendall, and Roberts found a similar solution for the case of adhesive contact.[5] This theory was rejected by Boris Derjaguin and co-workers[6] who proposed a different theory of adhesion[7] in the 1970s. The Derjaguin model came to be known as the DMT (after Derjaguin, Muller and Toporov) model,[7] and the Johnson et al. model came to be known as the JKR (after Johnson, Kendall and Roberts) model for adhesive elastic contact. This rejection proved to be instrumental in the development of the Tabor[8] and later Maugis[6] [9] parameters that quantify which contact model (of the JKR and DMT models) represent adhesive contact better for specific materials.
Further advancement in the field of contact mechanics in the mid-twentieth century may be attributed to names such as Bowden and Tabor. Bowden and Tabor were the first to emphasize the importance of surface roughness for bodies in contact.[10] [11] Through investigation of the surface roughness, the true contact area between friction partners is found to be less than the apparent contact area. Such understanding also drastically changed the direction of undertakings in tribology. The works of Bowden and Tabor yielded several theories in contact mechanics of rough surfaces.
The contributions of Archard (1957)[12] must also be mentioned in discussion of pioneering works in this field. Archard concluded that, even for rough elastic surfaces, the contact area is approximately proportional to the normal force. Further important insights along these lines were provided by Greenwood and Williamson (1966),[13] Bush (1975),[14] and Persson (2002).[15] The main findings of these works were that the true contact surface in rough materials is generally proportional to the normal force, while the parameters of individual micro-contacts (i.e., pressure, size of the micro-contact) are only weakly dependent upon the load.
The theory of contact between elastic bodies can be used to find contact areas and indentation depths for simple geometries. Some commonly used solutions are listed below. The theory used to compute these solutions is discussed later in the article. Solutions for multitude of other technically relevant shapes, e.g. the truncated cone, the worn sphere, rough profiles, hollow cylinders, etc. can be found in [16]
R
d
a=\sqrt{Rd}
The applied force
F
d
F=
| 4 | |
| 3 |
E*R
| ||||
| ||||
| d |
where
| 1 | |
| E* |
=
| |||||||||
| E1 |
+
| |||||||||
| E2 |
and
E1
E2
\nu1
\nu2
The distribution of normal pressure in the contact area as a function of distance from the center of the circle is[1]
p(r)=p0\left(1-
| r2 | |
| a2 |
| ||||
| \right) |
where
p0
p0=
| 3F | |
| 2\pia2 |
=
| 1 | \left( | |
| \pi |
| 6F{E* | |
| 2}{R |
2}\right)
| ||||
The radius of the circle is related to the applied load
F
a3=\cfrac{3FR}{4E*}
The total deformation
d
d=
| a2 | |
| R |
=\left(
| 9F2 | |
| 16{E* |
2R}\right)
| ||||
The maximum shear stress occurs in the interior at
z ≈ 0.49a
\nu=0.33
For contact between two spheres of radii
R1
R2
a
R
| 1 | |
| R |
=
| 1 | |
| R1 |
+
| 1 | |
| R2 |
This is equivalent to contact between a sphere of radius
R
If a rigid cylinder is pressed into an elastic half-space, it creates a pressure distribution described by[17]
p(r)=p0\left(1-
| r2 | |
| R2 |
| ||||
| \right) |
where
R
p0=
| 1 | |
| \pi |
| ||||
| E |
The relationship between the indentation depth and the normal force is given by
F=2RE*d
In the case of indentation of an elastic half-space of Young's modulus
E
\epsilon
a
\epsilon=a\tan(\theta)
with
\theta
d
d=
| \pi | |
| 2 |
\epsilon
The total force is
F=
| \piE | |
| 2\left(1-\nu2\right) |
a2\tan(\theta) =
| 2E | |
| \pi\left(1-\nu2\right) |
| d2 | |
| \tan(\theta) |
The pressure distribution is given by
p\left(r\right) =
| Ed | ln\left( | |
| \pia\left(1-\nu2\right) |
| a | |
| r |
+\sqrt{\left(
| a | |
| r |
\right)2-1}\right) =
| Ed | |
| \pia\left(1-\nu2\right) |
\cosh-1\left(
| a | |
| r |
\right)
The stress has a logarithmic singularity at the tip of the cone.
In contact between two cylinders with parallel axes, the force is linearly proportional to the length of cylinders L and to the indentation depth d:[18]
F ≈
| \pi | |
| 4 |
E*Ld
The radii of curvature are entirely absent from this relationship. The contact radius is described through the usual relationship
a=\sqrt{Rd}
with
| 1 | |
| R |
=
| 1 | |
| R1 |
+
| 1 | |
| R2 |
as in contact between two spheres. The maximum pressure is equal to
p0=\left(
| E*F | |
| \piLR |
| ||||
| \right) |
See main article: Bearing pressure.
The contact in the case of bearings is often a contact between a convex surface (male cylinder or sphere) and a concave surface (female cylinder or sphere: bore or hemispherical cup).
Some contact problems can be solved with the Method of Dimensionality Reduction (MDR). In this method, the initial three-dimensional system is replaced with a contact of a body with a linear elastic or viscoelastic foundation (see fig.). The properties of one-dimensional systems coincide exactly with those of the original three-dimensional system, if the form of the bodies is modified and the elements of the foundation are defined according to the rules of the MDR.[19] [20] MDR is based on the solution to axisymmetric contact problems first obtained by Ludwig Föppl (1941) and Gerhard Schubert (1942)[21]
However, for exact analytical results, it is required that the contact problem is axisymmetric and the contacts are compact.
The classical theory of contact focused primarily on non-adhesive contact where no tension force is allowed to occur within the contact area, i.e., contacting bodies can be separated without adhesion forces. Several analytical and numerical approaches have been used to solve contact problems that satisfy the no-adhesion condition. Complex forces and moments are transmitted between the bodies where they touch, so problems in contact mechanics can become quite sophisticated. In addition, the contact stresses are usually a nonlinear function of the deformation. To simplify the solution procedure, a frame of reference is usually defined in which the objects (possibly in motion relative to one another) are static. They interact through surface tractions (or pressures/stresses) at their interface.
As an example, consider two objects which meet at some surface
S
x
y
z
pz=p(x,y)=qz(x,y)
qx=qx(x,y)
qy=qy(x,y)
S
Pz=\intSp(x,y)~dA~;~~Qx=\intSqx(x,y)~dA~;~~Qy=\intSqy(x,y)~dA
Mx=\intSy~qz(x,y)~dA~;~~My=\intS-x~qz(x,y)~dA~;~~Mz=\intS[x~qy(x,y)-y~qx(x,y)]~dA
The following assumptions are made in determining the solutions of Hertzian contact problems:
Additional complications arise when some or all these assumptions are violated and such contact problems are usually called non-Hertzian.
Analytical solution methods for non-adhesive contact problem can be classified into two types based on the geometry of the area of contact.[22] A conforming contact is one in which the two bodies touch at multiple points before any deformation takes place (i.e., they just "fit together"). A non-conforming contact is one in which the shapes of the bodies are dissimilar enough that, under zero load, they only touch at a point (or possibly along a line). In the non-conforming case, the contact area is small compared to the sizes of the objects and the stresses are highly concentrated in this area. Such a contact is called concentrated, otherwise it is called diversified.
A common approach in linear elasticity is to superpose a number of solutions each of which corresponds to a point load acting over the area of contact. For example, in the case of loading of a half-plane, the Flamant solution is often used as a starting point and then generalized to various shapes of the area of contact. The force and moment balances between the two bodies in contact act as additional constraints to the solution.
See main article: Flamant solution. A starting point for solving contact problems is to understand the effect of a "point-load" applied to an isotropic, homogeneous, and linear elastic half-plane, shown in the figure to the right. The problem may be either plane stress or plane strain. This is a boundary value problem of linear elasticity subject to the traction boundary conditions:
\sigmaxz(x,0)=0~;~~\sigmaz(x,z)=-P\delta(x,z)
where
\delta(x,z)
\begin{align} \sigmaxx&=-
| 2P | |
| \pi |
| x2z | |
| \left(x2+z2\right)2 |
\\ \sigmazz&=-
| 2P | |
| \pi |
| z3 | |
| \left(x2+z2\right)2 |
\\ \sigmaxz&=-
| 2P | |
| \pi |
| xz2 | |
| \left(x2+z2\right)2 |
\end{align}
for some point,
(x,y)
Suppose, rather than a point load
P
p(x)
a<x<b
\begin{align} \sigmaxx&=-
| 2z | |
| \pi |
| ||||
| \int | ||||
| a |
~;~~ \sigmazz=-
| 2z3 | |
| \pi |
| ||||
| \int | ||||
| a |
\\[3pt] \sigmaxz&=-
| 2z2 | |
| \pi |
| ||||
| \int | ||||
| a |
\end{align}
The same principle applies for loading on the surface in the plane of the surface. These kinds of tractions would tend to arise as a result of friction. The solution is similar the above (for both singular loads
Q
q(x)
\begin{align} \sigmaxx&=-
| 2 | |
| \pi |
| ||||
| \int | ||||
| a |
~;~~ \sigmazz=-
| 2z2 | |
| \pi |
| ||||
| \int | ||||
| a |
\\[3pt] \sigmaxz&=-
| 2z | |
| \pi |
| ||||
| \int | ||||
| a |
\end{align}
These results may themselves be superposed onto those given above for normal loading to deal with more complex loads.
Analogously to the Flamant solution for the 2D half-plane, fundamental solutions are known for the linearly elastic 3D half-space as well. These were found by Boussinesq for a concentrated normal load and by Cerruti for a tangential load. See the section on this in Linear elasticity.
Distinctions between conforming and non-conforming contact do not have to be made when numerical solution schemes are employed to solve contact problems. These methods do not rely on further assumptions within the solution process since they base solely on the general formulation of the underlying equations.[23] [24] [25] [26] [27] Besides the standard equations describing the deformation and motion of bodies two additional inequalities can be formulated. The first simply restricts the motion and deformation of the bodies by the assumption that no penetration can occur. Hence the gap
h
h\ge0
where
h=0
\sigman=t ⋅ n
At locations where there is contact between the surfaces the gap is zero, i.e.
h=0
\sigman<0
\sigman=0
h>0
h\ge0, \sigman\le0, \sigmanh=0.
These conditions are valid in a general way. The mathematical formulation of the gap depends upon the kinematics of the underlying theory of the solid (e.g., linear or nonlinear solid in two- or three dimensions, beam or shell model). By restating the normal stress
\sigman
p
p=-\sigman
h0
g
u
u
p
After discretization the linear elastic contact mechanics problem can be stated in standard Linear Complementarity Problem (LCP) form.[28]
\begin{align} h&=h0+g+Cp,\\ h ⋅ p&=0,p\geq0,h\geq0,\\ \end{align}
where
C
When two bodies with rough surfaces are pressed against each other, the true contact area formed between the two bodies,
A
A0
In contact between a "random rough" surface and an elastic half-space, the true contact area is related to the normal force
F
| A= | \kappa |
| E*h' |
F
h'
\kappa ≈ 2
pav=
| F | ≈ | |
| A |
| 1 | |
| 2 |
E*h'
E*
h'
Greenwood and Williamson in 1966 (GW) proposed a theory of elastic contact mechanics of rough surfaces which is today the foundation of many theories in tribology (friction, adhesion, thermal and electrical conductance, wear, etc.). They considered the contact between a smooth rigid plane and a nominally flat deformable rough surface covered with round tip asperities of the same radius R. Their theory assumes that the deformation of each asperity is independent of that of its neighbours and is described by the Hertz model. The heights of asperities have a random distribution. The probability that asperity height is between
z
z+dz
\phi(z)dz
Ar
n=
| infty | |
| N\int | |
| d |
\phi(z)dz
The expected total area of contact can be calculated from the formula
Aa=N\piR
| infty | |
| \int | |
| d |
(z-d)\phi(z)dz
and the expected total force is given by
P=
| 4 | |
| 3 |
NEr\sqrt{R}
| infty | |
| \int | |
| d |
(z-
| ||||
| d) |
\phi(z)dz
where:
R, radius of curvature of the microasperity,
z, height of the microasperity measured from the profile line,
d, close the surface,
Er=\left(
| |||||||||
| E1 |
+
| |||||||||
| E2 |
\right)-1
Ei
\nui
Greenwood and Williamson introduced standardized separation
h=d/\sigma
\phi*(s)
\begin{align} Fn(h)&=
| infty | |
| \int | |
| h |
(s-h)n\phi*(s)ds\\ n&=ηAnF0(h)\\ Aa&=\piηAR\sigmaF1(h)\\ P&=
| 4 | |
| 3 |
ηAEr\sqrt{R}
| ||||
| \sigma |
| F | ||||
|
(h) \end{align}
where:
d is the separation,
A
η
E*
A
P
Fn(h)
\phi*(s)
Fn(h)
Fn(h)
Recently the exact approximants to
Ar
P
Fn(h)
Fn(h)=
| a0+a1h+a2h2+a3h3 | \exp\left(- | |||||||
|
| h2 | |
| 2 |
\right)
For
F1(h)
\begin{align}[] [a0,a1,a2,a3]&=[0.398942280401,0.159773702775,0.0389687688311,0.00364356495452]\\[] [b1,b2,b3,b4,b5,b6]&=\left[1.653807476138,1.170419428529,0.448892964428,0.0951971709160,0.00931642803836,-6.383774657279 x 10-6\right] \end{align}
The maximum relative error is
9.93 x 10-8%
For
| F | ||||
|
(h)
\begin{align}[] [a0,a1,a2,a3]&=[0.430019993662,0.101979509447,0.0229040629580,0.000688602924]\\[] [b1,b2,b3,b4,b5,b6]&=[1.671117125984,1.199586555505,0.46936532151,0.102632881122,0.010686348714,0.0000517200271] \end{align}
The maximum relative error is
1.91 x 10-7%
Fn(h)
\begin{align} F1(h)&=
| 1 | |
| \sqrt{2\pi |
where erfc(z) means the complementary error function and
K\nu(z)
For the situation where the asperities on the two surfaces have a Gaussian height distribution and the peaks can be assumed to be spherical,[38] the average contact pressure is sufficient to cause yield when
pav=1.1\sigmay ≈ 0.39\sigma0
\sigmay
\sigma0
\Psi
The Greenwood-Williamson model requires knowledge of two statistically dependent quantities; the standard deviation of the surface roughness and the curvature of the asperity peaks. An alternative definition of the plasticity index has been given by Mikic.[39] Yield occurs when the pressure is greater than the uniaxial yield stress. Since the yield stress is proportional to the indentation hardness
\sigma0
\Psi=
| E*h' | |
| \sigma0 |
>
| 2 | |
| 3 |
~.
In this definition
\Psi
\Psi<
| 2 | |
| 3 |
In both the Greenwood-Williamson and Mikic models the load is assumed to be proportional to the deformed area. Hence, whether the system behaves plastically or elastically is independent of the applied normal force.[1]
The model proposed by Greenwood and Tripp (GT),[40] extended the GW model to contact between two rough surfaces. The GT model is widely used in the field of elastohydrodynamic analysis.
The most frequently cited equations given by the GT model are for the asperity contact area
Aa=\pi2(η\beta\sigma)2AF2(λ),
and load carried by asperities
P=
| 8\sqrt{2 | |
where:
η\beta\sigma
A
λ
λ=h/\sigma
E'
F2,
| F | ||||
|
(λ)
Leighton et al. presented fits for crosshatched IC engine cylinder liner surfaces together with a process for determining the
Fn(h)
The exact solutions for
Aa
P
Fn
\begin{align} F2&=
| 1 | |
| 2 |
\left(h2+1\right)\operatorname{erfc}\left(
| h | |
| \sqrt{2 |
where erfc(z) means the complementary error function and
K\nu(z)
In paper one can find comprehensive review of existing approximants to
| F | ||||
|
| F | ||||
|
F2
Fn(h)
Fn(h)=
| a0+a1h+a2h2+a3h3 | \exp\left(- | |
| 1+b1h+b2h2+b3h3+b4h4+b5h5+b6h6 |
| h2 | |
| 2 |
\right)
For
F2(h)
\begin{align}[] [a0,a1,a2,a3]&=[0.5,0.182536384941,0.039812283118,0.003684879001]\\[][b1,b2,b3,b4,b5,b6]&=[1.960841785003,1.708677456715,0.856592986083,0.264996791567,0.049257843893,0.004640740133] \end{align}
The maximum relative error is
1.68 x 10-7%
For
| F | ||||
|
(h)
\begin{align}[] [a0,a1,a2,a3]&=[0.616634218997,0.108855827811,0.023453835635,0.000449332509]\\[] [b1,b2,b3,b4,b5,b6]&=[1.919948267476,1.635304362591,0.799392556572,0.240278859212,0.043178653945,0.003863334276] \end{align}
The maximum relative error is
4.98 x 10-8%
When two solid surfaces are brought into close proximity, they experience attractive van der Waals forces. Bradley's van der Waals model[41] provides a means of calculating the tensile force between two rigid spheres with perfectly smooth surfaces. The Hertzian model of contact does not consider adhesion possible. However, in the late 1960s, several contradictions were observed when the Hertz theory was compared with experiments involving contact between rubber and glass spheres.
It was observed[5] that, though Hertz theory applied at large loads, at low loads
This indicated that adhesive forces were at work. The Johnson-Kendall-Roberts (JKR) model and the Derjaguin-Muller-Toporov (DMT) models were the first to incorporate adhesion into Hertzian contact.
It is commonly assumed that the surface force between two atomic planes at a distance
z
F(z)=\cfrac{16\gamma}{3z0}\left[\left(\cfrac{z}{z
| -9 | |
| 0}\right) |
-
| -3 | |
| \left(\cfrac{z}{z | |
| 0}\right) |
\right]
F
2\gamma
z0
The Bradley model applied the Lennard-Jones potential to find the force of adhesion between two rigid spheres. The total force between the spheres is found to be
Fa(z)=\cfrac{16\gamma\pi
| -8 | |
| R}{3}\left[\cfrac{1}{4}\left(\cfrac{z}{z | |
| 0}\right) |
-
| -2 | |
| \left(\cfrac{z}{z | |
| 0}\right) |
\right]~;~~
| 1 | |
| R |
=
| 1 | |
| R1 |
+
| 1 | |
| R2 |
R1,R2
The two spheres separate completely when the pull-off force is achieved at
z=z0
Fa=Fc=-4\gamma\piR.
To incorporate the effect of adhesion in Hertzian contact, Johnson, Kendall, and Roberts[5] formulated the JKR theory of adhesive contact using a balance between the stored elastic energy and the loss in surface energy. The JKR model considers the effect of contact pressure and adhesion only inside the area of contact. The general solution for the pressure distribution in the contact area in the JKR model is
p(r)=p0\left(1-
| r2 | |
| a2 |
| ||||
| \right) |
+p0'\left(1-
| r2 | |
| a2 |
| ||||
| \right) |
Note that in the original Hertz theory, the term containing
p0'
p0=
| 2aE* | |
| \piR |
; p0'=-\left(
| 4\gammaE* | |
| \pia |
| ||||
| \right) |
where
a
F
2\gamma
Ri,Ei,\nui,~~i=1,2
| 1 | |
| R |
=
| 1 | |
| R1 |
+
| 1 | |
| R2 |
;
| 1 | |
| E* |
=
| |||||||||
| E1 |
+
| |||||||||
| E2 |
The approach distance between the two spheres is given by
d=
| \pia | |
| 2E* |
\left(p0+2p0'\right)=
| a2 | |
| R |
The Hertz equation for the area of contact between two spheres, modified to take into account the surface energy, has the form
a3=
| 3R | |
| 4E* |
\left(F+6\gamma\piR+\sqrt{12\gamma\piRF+(6\gamma\piR)2}\right)
When the surface energy is zero,
\gamma=0
a3=
| 9R2\gamma\pi | |
| E* |
The tensile load at which the spheres are separated (i.e.,
a=0
Fc=-3\gamma\piR
This force is also called the pull-off force. Note that this force is independent of the moduli of the two spheres. However, there is another possible solution for the value of
a
ac
| 3 | |
| a | |
| c |
=
| 9R2\gamma\pi | |
| 4E* |
If we define the work of adhesion as
\Delta\gamma=\gamma1+\gamma2-\gamma12
where
\gamma1,\gamma2
\gamma12
a3=
| 3R | |
| 4E* |
\left(F+3\Delta\gamma\piR+\sqrt{6\Delta\gamma\piRF+(3\Delta\gamma\piR)2}\right)
The tensile load at separation is
F=-
| 3 | |
| 2 |
\Delta\gamma\piR
and the critical contact radius is given by
| 3 | |
| a | |
| c |
=
| 9R2\Delta\gamma\pi | |
| 8E* |
The critical depth of penetration is
dc=
| |||||||
| R |
=
| ||||
| \left(R |
| 9\Delta\gamma\pi | |
| 4E* |
| ||||
| \right) |
The Derjaguin-Muller-Toporov (DMT) model[7] [42] is an alternative model for adhesive contact which assumes that the contact profile remains the same as in Hertzian contact but with additional attractive interactions outside the area of contact.
The radius of contact between two spheres from DMT theory is
a3=\cfrac{3R}{4E*}\left(F+4\gamma\piR\right)
Fc=-4\gamma\piR
In terms of the work of adhesion
\Delta\gamma
a3=\cfrac{3R}{4E*}\left(F+2\Delta\gamma\piR\right)
Fc=-2\Delta\gamma\piR
In 1977, Tabor[43] showed that the apparent contradiction between the JKR and DMT theories could be resolved by noting that the two theories were the extreme limits of a single theory parametrized by the Tabor parameter (
\mu
\mu:=
| dc | |
| z0 |
≈ \left[
| R(\Delta\gamma)2 | |
| {E* |
2
| 3}\right] | |
| z | |
| 0 |
| ||||
where
z0
\mu
\mu
Subsequently, Derjaguin and his collaborators[44] by applying Bradley's surface force law to an elastic half space, confirmed that as the Tabor parameter increases, the pull-off force falls from the Bradley value
2\piR\Delta\gamma
(3/2)\piR\Delta\gamma
Further improvement to the Tabor idea was provided by Maugis[9] who represented the surface force in terms of a Dugdale cohesive zone approximation such that the work of adhesion is given by
\Delta\gamma=\sigma0~h0
where
\sigma0
h0
z0\lez\lez0+h0
a
\sigma0
c>a
a<r<c
h(r)
h(a)=0
h(c)=h0
m
m:=
| c | |
| a |
In the Maugis-Dugdale theory,[47] the surface traction distribution is divided into two parts - one due to the Hertz contact pressure and the other from the Dugdale adhesive stress. Hertz contact is assumed in the region
-a<r<a
pH(r)=\left(
| 3FH | |
| 2\pia2 |
\right)\left(1-
| r2 | |
| a2 |
| ||||
| \right) |
where the Hertz contact force
FH
FH=
| 4E*a3 | |
| 3R |
The penetration due to elastic compression is
dH=
| a2 | |
| R |
The vertical displacement at
r=c
uH(c)=\cfrac{1}{\piR}\left[a2\left(2-m2\right)\sin-1\left(
| 1 | |
| m |
\right)+a2\sqrt{m2-1}\right]
and the separation between the two surfaces at
r=c
hH(c)=
| c2 | |
| 2R |
-dH+uH(c)
The surface traction distribution due to the adhesive Dugdale stress is
pD(r)=\begin{cases} -
| \sigma0 | |
| \pi |
\cos-1\left[
| |||||||||
|
\right]& for r\lea\\ -\sigma0& for a\ler\lec \end{cases}
The total adhesive force is then given by
FD=-2\sigma0m2a2\left[\cos-1\left(
| 1 | |
| m |
\right)+
| 1 | |
| m2 |
\sqrt{m2-1}\right]
The compression due to Dugdale adhesion is
dD=-\left(
| 2\sigma0a | |
| E* |
\right)\sqrt{m2-1}
and the gap at
r=c
hD(c)=\left(
| 4\sigma0a | |
| \piE* |
\right)\left[\sqrt{m2-1}\cos-1\left(
| 1 | |
| m |
\right)+1-m\right]
The net traction on the contact area is then given by
p(r)=pH(r)+pD(r)
F=FH+FD
h(c)=hH(c)+hD(c)=h0
Non-dimensionalized values of
a,c,F,d
\bar{a}=\alphaa~;~~\bar{c}:=\alphac~;~~\bar{d}:=\alpha2Rd~;~~ \alpha:=\left(
| 4E* | |
| 3\pi\Delta\gammaR2 |
| ||||
| \right) |
~;~~ \bar{A}:=\pic2~;~~\bar{F}=
| F | |
| \pi\Delta\gammaR |
In addition, Maugis proposed a parameter
λ
\mu
λ:=
| 2}\right) | ||||
| \sigma | ||||
|
| ||||
≈ 1.16\mu
where the step cohesive stress
\sigma0
\sigmath=
| 16\Delta\gamma | |
| 9\sqrt{3 |
z0}
Zheng and Yu [48] suggested another value for the step cohesive stress
\sigma0=\exp\left(-
| 223 | |
| 420 |
\right) ⋅
| \Delta\gamma | |
| z0 |
≈ 0.588
| \Delta\gamma | |
| z0 |
to match the Lennard-Jones potential, which leads to
λ ≈ 0.663\mu
Then the net contact force may be expressed as
\bar{F}=\bar{a}3-λ\bar{a}2\left[\sqrt{m2-1}+m2\sec-1m\right]
and the elastic compression as
\bar{d}=\bar{a}2-
| 4 | |
| 3 |
~λ\bar{a}\sqrt{m2-1}
The equation for the cohesive gap between the two bodies takes the form
| λ\bar{a | |
| 2}{2}\left[\left(m |
2-2\right)\sec-1m+\sqrt{m2-1}\right]+
| 4λ\bar{a | |
This equation can be solved to obtain values of
c
a
λ
λ
m → 1
λ
The Maugis-Dugdale model can only be solved iteratively if the value of
λ
a
a=a0(\beta)\left(
| \beta+\sqrt{1-F/Fc(\beta) | |
where
a0
\beta
λ
λ ≈ -0.924ln(1-1.02\beta)
The case
\beta=1
\beta=0
0<\beta<1
0.1<λ<5
Even in the presence of perfectly smooth surfaces, geometry can come into play in form of the macroscopic shape of the contacting region. When a rigid punch with flat but oddly shaped face is carefully pulled off its soft counterpart, its detachment occurs not instantaneously but detachment fronts start at pointed corners and travel inwards, until the final configuration is reached which for macroscopically isotropic shapes is almost circular. The main parameter determining the adhesive strength of flat contacts occurs to be the maximum linear size of the contact.[50] The process of detachment can as observed experimentally can be seen in the film.[51]
See Also: Contact Mechanics for Soft Hemi-Elliptical Fingertip