JOURNAL OF THEORETICAL

AND APPLIED MECHANICS

44, 1, pp. 51-73, Warsaw 2006

THE CLAMPED JOINTS – A SURVEY AND ANALYSIS OF
SHAPES AND MATERIALS

Janusz Juraszek

Department of Mechanical Engineering Fundamentals, University of Bielsko-Biała

e-mail: jjuraszek@ath.bielsko.pl

The paper presents a surveyof available joints of the clamped type (CJ),
which are of crucial importance in view of the design safety level. A
numerical analysis has been carried out to estimate the efficiency of a
given shape of the CJ. A digital database of material parameters most
often employed in CJs has been presented as well.

Key words: clamped joint; jaw shapes, FEM, stress-strain state

1. Applicability and analysis of clamped joints used in practice

Clamped joints, which can be classified as permanent joints, are often
used for connecting and fixing steel wire ropes, electric cables or hydraulic
conduits. For example, in the power engineering, joints of that type are used
for fixing and connecting different items; e.g., conductors, cables, elements of
overhead transmission lines, etc. In aviation, they are used as an alternative
way for making a control cable tip. Other examples can be found in cranes
(lifting rope tip) and in hydraulic piping (joining of conduits). Another type of
permanent joints connecting steelwire ropes consists infillinga jointwitha low
meltingalloy,which is,however, avery laborious, expensiveandtoxic (leadand
zinc vapours) process. Moreover, it cannot be used in all the aforementioned
cases.
On the other hand, it should be mentioned that temporary joints reveal

also some substantial disadvantages, e.g., complex design, large dimensions
and mass, which considerably rises costs of making such joints. The method
of clamping is relatively inexpensive, requires little work, and its broad ap-
plicability covers also outdoor cases. The main advantage of clamped joints
consists in its small size. A hexagonal clamped joint can be considered as a



52 J.Juraszek

typical example of such a joint [5]. Themain idea of fastening consists here in
changing the initial circular shape of a sleeve into a hexagon inscribed in that
circle (Fig.1). The process of clamping is performed using two clamping jaws.
The surface of the jaw contact determines the joint parting plane, which is
its plane of symmetry as well. In power engineering applications (Fig.2), the
Al-Fe (aluminium and steel) conductor tip after being inserted into a sleeve is
clamped due to transversal plastic deformation of the sleeve. The joint opera-
tion is two-fold, i.e. besides doing a mechanical work (i.e. carrying a load) it
operates also as a conductor so that the electric circle is not broken. Thema-
terial of the clamping sleeve should reveal good conducting properties, usually
the sleeve is made of aluminiumA0.

Fig. 1. Rope clamped ”into a hexagon”

Fig. 2. Exemplary joints used in power engineering systems



The clamped joints – a survey... 53

There are also other forms of clamping jaws available, e.g., octagon, do-
decagon, ellipsis, modified ellipsis, circle (one parting plane), modified circle,
axi-symmetric forms, etc. Some papers devoted to that problem can be fo-
und in the literature as well. Themost interesting publicationa are presented
below.
The distribution of pressure in the course of a clamping process in not

a uniform one. The way of axi-symmetric clamping proposed in Juraszek
(1995, 1997, 1999, 2000, 2004) eliminated noticeably that non-uniformity re-
vealed by the pressure distribution. That approach, however, requires ap-
plication of a special hydraulic power press of a complex design, and the
clamping process should be carried out at a laboratory or a suitable factory
department.
Another research that should be mentioned here consists in inventing a

newmethod for mounting wires for temperaturemeasurement in an oily seed
silo, based on mounting them into a self-clamping cone. The wires break off
along the radius of the inner hole-to-cone segment. The application of the axi-
symmetric way of clamping allowed for elimination of the wire breaking off
whichmade both the design andmounting much simpler.
Basing on the aforementioned examples, one can arrive at the conclusion

that clamped joints exert decisive influence upon a safety level and reliability
of structures they are applied to (fixing of lifting ropes in cranes, overhead
transmission line supports, electric cables, etc.). A proper qualitative strength
analysis may result in improving the safety and allowing for a proper choice
of joint parameters.
Each clamped joint comprises the following two elements:

1) rope, cable or a hydraulic conduit

2) clamping sleeve.

Steel wire ropes, electric cables and hydraulic hoses should meet require-
ments specified in relevant standards, while their properties are presented in
Juraszek (1992). Molnar et al. (Maligda et al., 2000; Molnar, 2004; Stanova
and Molnar, 2003) presented a problem of 3D modelling of ropes. A clam-
ping sleeve made of a plastic material is the second element of the joint. The
sleeve material deforms plastically when subject to an external pressure, and
after unloading the residual stresses remain on the sleeve-rope contact sur-
face. When modelling the phenomena appearing in the clamped joint, values
of material parameters introduced into the model after exceeding the yield
point are of crucial importance. The values of parameters available from the
literature differ substantially from those measured for a given material at its



54 J.Juraszek

working point or within the expected loading range. To make the calcula-
tions more accurate, the Digital Database of Material Parameters has been
proposed.

Most interesting research works on the contact problems between a wire
rope and foundation was presented by Dorfmann et al. (1999). The authors
carried out a numerical analysis and experimental investigations on the con-
tact between a rope and a rubber-aluminium wheel. Numerical simulations
were performed using the AbaQus code, with the phenomenon of wheel he-
ating introduced into the model, which, however, presented only a simplified
external contour instead of the real wires. Kliber (2000) carried out numerical
analyses of large plastic deformations with the phenomenon of linear strain
hardening included. Buczkowski and Kleiber (1992) examined models with
friction introduced into elastic-plastic problems.

The model of contact should be specified before analysing the process of
clamping of a wire rope. Altenbach (1991) presented an incremental method
for contact description in 2D models, while Hrycaj et al. (1999) showed an
elastic plasticmodelwith theCoulomb friction introduced. Among the papers
devoted to clamped joints, one should mention the analysis of clamping into
a hexagon (Juraszek, 1994), research onmulti-clip joints (Juraszek, 2004) and
a study on the equivalent transversal stiffness of a steel wire rope and steel-
aluminium cables (Juraszek, 1992, 1995).

Problems of large deformations in plastic forming were analysed by Mac-
DonaldandHashmi (2002) using theANSYScode.Landreet al. (2003) presen-
ted a discussion of FEMmesh changes during upset forgingwith theCockroft-
Latamcriterion taken into consideration. Provatidis (2003) showedan interpo-
lation of theCoon type applied to an axi-symmetrical problem, which allowed
for making the calculation timemuch shorter for non-linear problems of large
deformations.

Most often, joint designs result from the experience gained by different
manufacturers (Juraszek, 1997). A survey of designs available reveals the lack
of a consistent main idea laying behind the joint design. Moreover, one sho-
uld mention the lack of data on strength calculations, designing and appro-
priate selections of rope fastenings (connections between elements that reveal
substantially different stiffnesses). The investigations are being conducted by
scientific centres associated withmanufacturing companies and, consequently,
market competition prevents publication of the results. A survey of materials
used in clamped joints, having a systematic form of the Digital Database has
beenpresented hereinafter, togetherwith the discussion on shapes of clamping
jaw, taking into consideration the twisting of jaes about rope wires.



The clamped joints – a survey... 55

2. Digital Database (DD) of material parameters used in
calculations of clamped joints

2.1. Introduction

Materials used in clamped joints reveal a great variety of physical para-
meters. In the case of steel wire ropes, the sleeve is made of a high-plasticity
steel, while electric cables should be clamped with sleeves made of the alumi-
nium A0 or other aluminium alloys. The process of clamping involves large
plastic deformations. Therefore, one of the crucial phases of the clamped joint
modelling consists in a detailed analysis of characteristics of the materials to
be joined, focusing on the material parameters beyond the yield point.
A new systematic approach has been proposed allowing for a consistent

presentation of material parameters that can be applied to joints, providing
at the same time a way of producing digital forms of material characteristics.
Differentmodels of amaterial canbe constructed aswell, bymeans of a special
program the database is supplied with. The possibility has also been offered
to find necessary parameters for analysis of a non-linear material.
Nowadays, some databases are available:

• created by theCentre of Excellence for Safety-Critical Pressure Systems
(www.ippt.gov.pl/centrum-cdsc/baza); it contains only characteristics of
materials usedwhen constructing pressure vessels, providing however no
discussion of material properties beyond the yield point;

• established by the Centre for Advanced Materials and Technologies – a
catalogue of newmaterials;

• very large database www.matweb.com;

• database of parameters www.suppliersoline.com and

• database of material properties depending on temperature
www.jam.software.inc.

Unfortunately, they do not provide any data allowing for precise determina-
tion of the properties of materials used in clamped joints, especially beyond
the yield point. There are only standard material characteristics available;
providing values of Re,Rm,A5,A10,E andhardeningmodulus, without any
specification of the strain range forwhich they have been determined.There is
a lack of accurate data on the strain-hardening coefficient at an arbitrary po-
int of the characteristics. Typical material catalogues (e.g. Dobrzański, 2001)
concentrate on a chemical constitution and the aforementioned standard pa-
rameters. Bures and Kohutek (2000) presented constructional possibilities of



56 J.Juraszek

material databases using the Internet. A new solution to the problem has be-
en proposed based on the enormous capabilities offered bymodern, advanced
experimental equipment that satisfies the needs for data necessary to carry
out a non-linear numerical analysis using FEM. The research scope covered
allmaterials used in clamped joints, which can be classified into several groups
depending on their application:
• Low-carbon plastic steels, e.g. steel of 10 grade – clamping sleeve

• High-carbon steels, assisting sleeve in hydraulic joints

• Aluminium and its alloys, e.g. aluminiumA0 – clamping sleeve working
as conductor in electric joints

• Wires of ropes

• Wires of electric cables

• Hoses in hydraulic systems – elastomers and polymers

• Superplastic materials like NITINOL.

The values of characteristic parameters of materials used in joints of that
type differ fundamentally, e.g., the value of Young’smodulus varies within the
range from 2MPa (elastomers) to 210000MPa (steels).
A new database has been proposed for material parameters necessary in

numerical investigations on clamped joints. To the best author’s knowledge,
the approach put forward has not been taken before. It allows for automatic
data collecting from experiments performed using the general-purpose testing
machine INSTRONaswell as fordataprocessing to arrive at the formrequired
by the FEM approach. The numerical analysis is carried out basing on true
values of the tangentialmodulusdetermined for a given load. Suchanapproach
improves accuracy of numerical calculations, assuming at the same time the
role of pre-processor of material parameters necessary for analysis of plastic
deformation problems.
The database proposed allows for a proper material choice for new types

of joints, improving that way their safety. Capabilities of modern computer
techniques enable application of values of parameters stored in the database
to the analysis carried out basing on non-linear physical relationships.
Therefore, one can now attempt at a numerical analysis based on true

properties of a material determined within the whole expected loading range.
It should be noted, however, that the values resulting from experiments differ
substantially from those presented in the literature.
A special computer program has been developed, which:
• downloads resultsof strength testing fromthe INSTRONmachine,which
could have been interpreted only by the machine software;



The clamped joints – a survey... 57

• processes these results to arrive at the form allowing for data transfer to
the FEM code;

• determines parameters necessary for the non-linear analysis.

2.2. Models of materials available in the DD base

The DD database offers a special computer program that allows for pro-
ducing a series ofmodels of materials that can be used in the non-linear FEM
analysis. The applied simplifying approach most often consists in neglecting
”the plasticity platform” and substituting a segment of constant inclination
for an exponential hardening. The model obtained that way is called biline-
ar and comprises two segments of different angles of inclination. The tangent
of the inclination angle the first segment makes with the axis ε represents
Young’smodulus (elastic range), while the second segment represents the pla-
stic range determined by the hardening modulus E′. The common point of
both segments represents the elastic limit Re.

Fig. 3. Bilinear andmulti-linear models of the consideredmaterial

To attain higher calculation accuracy in the elastic-plastic analysis, one
can represent the true stress-strain curve using more segments, e.g. with a
broken line comprising 5 segments. Such a model is called multi-linear. The
provided computer program allows also for developing models having form of
an exponential curve or a polynomial.
When designing clamped joints for hydraulic conduits, a hose made of an

elastomer (often reinforced) fitted into a socket is the element to be clamped.
In the case of steel-rubber ropes, the space amongwires is filledwith a special
mixture of elastomers.Material properties of the elastomer are represented by
the hyper-elastic Mooney-Rivlin model.
When modelling bodies made of rubber or other materials revealing non-

linear elasticity and incompressibility, one should apply hyper-elastic models



58 J.Juraszek

Fig. 4. Hyper-elasticMooney-Rivlin model

to analysis carried out within the range of large deformations. Practically, the
following two approaches to the problem are incorporated most commonly.
The first one consists in the interpolation of stress components separately,
while in the second one the apparent compressibility is introduced together
with a relationship limiting the number of unknown degrees of freedom in the
global stiffness matrix.
The Mooney-Rivlin equation has been employed for describing properties

of elastomers
σ=2C1(α−α

−2)+2C2(1−α
−)

where
σ – normal stress
C1,C2 – Mooney’s constants
α – l/l0 deformation.
The constant C1 assumes values within the range 0.05-0.2MPa rising as

the vulcanisation level rises, while the constant C2 depends on the rubber
hardness (0.05-0.1MPa).
After calculating thederivative of theMooney-Rivlin equationwith respect

to ε, one arrives at a formula for the equivalent modulus Ez

Ez =
dσ

dα

∣

∣

∣

α=1
=4C1+6C2

Values of C1 and C2 are automatically determinedby importing theprocessed
table of σ−εdata (resulting fromthe compression curve) to theANSYScode,
and then using theMoon function.
Anothergroupofmaterials used in clamped joints comprises shapememory

alloys. Figure 5 shows exemplary characteristics of Nitinol.
Models of shapememorymaterials were presented byTanaka et al. (1986),

whileAuricchio (2001), Brinson (1993), Jung et al. (2002) showedmodelswith
thermodynamic effects included.



The clamped joints – a survey... 59

Fig. 5. Nitinol characteristics with phase transitions taken into consideration

The constitutive model (pseudoelastic, bilinear) bases on the directional
strain components that have been determined. The model is based upon the
double trigger line concept, according towhich the gradient of the stress–strain
curve depends on the sign of the deformation speed

CZ =























E1(εz, ε̇z,τz)∈ΩA(T)

E2(εz, ε̇z,τz)∈ΩAM(T)

E3εz, ε̇z,τz)∈ΩM(T)

E4(εz, ε̇z,τz)∈ΩMA(T)

where εz denotes the strain and the dot above it – the strain speed.

Fig. 6. Nitral characteristics – 7% deformations

Figure 6 presents characteristics found from experiments with a characte-
ristic loop due to phase transitions involved by a temperature drop down to
183◦C, when deformations reach 7%.



60 J.Juraszek

2.3. Description of the computer program

The program ”Digital database of material parameters” has been deve-
loped to improve the accuracy of FEM numerical calculations. At the same
time, it allows for:

• application of true material characteristics;

• determination of the Youngmodulus at an arbitrary point of the stress-
strain curve in tension or compression;

• linear interpolation of the stress-strain curve in tension or compression
in terms of a broken line passing through 5 points;

• using the exponential or polynomial model.

A samplewindowof the program is shown inFig.7. There is a stress-strain
curve visible on the screen together with values of deformation (column X)
and the corresponding force (column Y ) basing on which the diagram was
generated. The user can scale the display up or down, delete the picture or
store it in a hard disc (see Fig.7).

Fig. 7. A view of the computer screen after rolling in the data (in Polish)

Theprogramproposed allows for determination of theYoungmodulus (i.e.
themodulus representedby the tangent to a givenpoint of thediagram,within
the non-linear range of course) at every chosen point within themeasurement
range. Additionally, for a given range, one can determine the so-called secant
modulus (i.e. represented by the secant to a given point of the diagramwithin
the non-linear range).When indicating anarbitrarypoint on thediagramwith
amouse cursor, the user candetermine theYoungmodulus.For the purpose of



The clamped joints – a survey... 61

storingdiagrams in computermemoryaswell as disseminating the information
via the Internet, a special module was developed for storing the items in the
form of GIF image files with their quality being maintained.

Fig. 8. Sample diagrams saved using the graphics module

When making measurements using the INSTRON machine, one obtains
results in the form of a file, which, up till now, could have been interpreted
only by thatmachine. Clicking on the ”Converter” dropdown list box one can
roll in such a file, browse or convert it, i.e. store in the form of a common text
file containing two data columns necessary for generation of the stress-strain
curve.
The aforementioned database provides also a model allowing for rolling

in the data registered by the specific software of the general-purpose testing
machine INSTRON, and for processing files containing measurement results
into the form required by theANSYS code.Material parameters necessary for
non-linear analysis are determined as well, depending on the adopted model
of the consideredmaterial. It is obvious that the program is user-friendly. The
databasepresentedallowsalso for storingandcomparingbetween the results of
other experiments. The possibility of introducing truematerial characteristics
and taking the expected loading range into account improves the accuracy of
numerical calculations.

3. Theoretical background

The present research aims at the analysis of the stress-state in clamped
joints with clamping sleeves of different shapes. The following assumptions
have been accepted:



62 J.Juraszek

• the clamping process is quasi-static;

• the plane model is employed with the joint width neglected;

• twisted steel lines of the T1x7 type are considered which implies that
that a relatively long length of lay twisting of the rope strands can be
neglected;

• three-node Contac48 elements represent the contact zone between the
sleeve and rope;

• kinematic hardening of the material is introduced into the model.

The theoretical background of themethod is presentedbelow.The changes
inmaterial parameters in the course of the deformation process are taken into
account. TheAmont-Coulomb frictonmodel is introduced into the sleeve-rope
contact area. The clamping process is assumedas a quasi-static one. TheFEM
approach assists the analysis of plastic deformation problems.
The equation of equilibrium for amedium can be derived from the virtual

workprinciple (Kleiber, 1984). In the case of a general Lagrange’s formulation,
we have

∫

V

Sijδεij dV =R (3.1)

where
Sij – component of the second Piola-Kirchoff stress tensor
εij – component of the Green-Lagrange strain tensor.

Thework done by the external forces R can be represented in terms of the
surface and volume works, respectively

R=
∫

A

pδUk da+
∫

V

fδUk dV (3.2)

The above equation has been derived on the assumption that the body
configuration changes from one loading step to another.
In Eq. (3.2), the symbols A and V stand for the surface and volume, of

the body, respectively, while p and f represent components of the vectors of
surface and volume forces acting upon a unit surface and unit volume of the
body corresponding to the initial configuration. δUk represents the displace-
ment variation while δteij stand for the strain variations

δkeij = δ
1
2
(kUi,j + kUj,i) (3.3)



The clamped joints – a survey... 63

The above equation in the FEM approach can be rewritten in the following
discrete matrix form

k
K
k
U = k+1R− kF (3.4)

One can arrive at Eq. (3.4) after substituting the following matrix forms for
the integrands

∫

V 0

kσijδeij dV
0 =

0
∫

V

B
>

L
k
Σ dV 0 = kF

(3.5)

(

0
∫

V

B
>

LDBL dV
0
)

k
U = kKkU

The following denotation is used in Eqs (3.4) and (3.5):
k
K – tangential stiffness matrix at the loading step k
k
U – vector of node displacement increments at the loading step k
k+1
R – incremental vector of nodal loads at the loading step k+1

k
F – vector of nodal correcting forces at the loading step k
BL – so-called ”geometric” matrix relating strains to displace-

ments
D – matrix of material properties (tangential matrix)
k
Σ – vector of current stresses (at the step k).

The term ”step” throughout the considerations means subsequent incre-
mental loading steps.

4. Modelling of the process of clamping and unloading with the
shape of clamping jaws taken into consideration

Ashas beenmentioned above, the choice of type of clamped joints is usual-
lymade basing onmanufacturers’ experience. Themain issue to be considered
here consists in the analysis of clamping andunloading processes, respectively,
in theway allowing for proper assessment of states of displacements anddefor-
mations together with the stress state depending on the type of clamping jaws
employed. A one-plane hinged jaw of a hexagonal shape inscribed in a circle
is most commonly used. Such a jaw is very simple in use, and the clamping
process can be performed with a small flash of the clamped material. On the



64 J.Juraszek

opposite end of the application list, an axi-symmetrical jaw is located, being
used hardly ever. First to propose it for clamping of a twisted steel lines was
Juraszek (2000). For the axi-symmetrical clamping process to be performed,
four parting planes should be introduced and turned about 45 degrees relative
to each other, which highly complicates the clamping process. The used hy-
draulic systems prevent from simultaneous translation of the jaws. Therefore,
a mechanical system driving the translations of all jaws in a controlled way
combined with hydraulically driven motion were introduced which enabled
proper realisation of the axi- symmetrical clamping process. This approach
reveals very high complexity in view of the process technology. It should be
noted, however, that besides the two aforementioned ”extreme” types of jaws,
there are several other shapes available:

• Octagonal

• Octagonal-twisted

• Dodecagonal

• Dodecagonal-twisted

• Elliptic

• Modified elliptic

• Circular (one parting plane)

• Modified circular

• Of a special shape.

In the last case, roughly speaking, clamping jawshave a shape of a polygon
inscribed ina circle or ellipsis. Themain advantage of this type of jaws consists
in shaping its contours in theway ensuring additional displacements or proper
metal forming of the sleeve internal surface.
All the aforementioned types of clamping jaws have been analysed.
The presented jaws comprise all types used in practice as well as several

newly proposed. Some possibilities of their modifications are shown as well.
The clamped elementwas the ropeT1X7 – a very difficult one to bedealtwith
in such joints. A parametric model was produced allowing for introduction of
the ropewire diameterwith the corresponding external diameter. Table 1 lists
exemplary geometrical parameters of the rope. Both the internal and external
diameters are automatically chosen basing on the condition that the requ-
ired tensile strength should be equal to the tensile strength of the considered
rope.



The clamped joints – a survey... 65

Table 1. Exemplary normalised diameters of the rope (r) and wire
(w) [mm]

r w r w

0.63 0.2 3.6 1.2
0.7 0.22 4.0 1.3
0.8 0.26 4.5 1.5
0.9 0.3 5.0 1.6
1.0 0.33 5.5 1.8
1.1 0.36 6.3 2.0
1.2 0.4 7.0 2.2
1.4 0.45 8.0 2.6
1.6 0.52 9.0 3.0
1.8 0.6 10.0 3.2
2.0 0.65 12.0 4.0
2.2 0.7 15.0 4.7
2.5 0.8 18.0 6.0
2.8 0.9
3.2 1.0

Each of the presented jaws has at least two parting planes (Fig.9a) that
are, at the same time, two axes of symmetry. Basing on the symmetry of the
system, one can take into consideration only 1/4 of the clamped joint model
(Fig.9b). To arrive at the results for the whole joint – those obtained for one
quarter were mapped with respect to the corresponding axes. That allowed
for shortening of the calculation time by 83% and reduction of the resulting
file size by 68%.

Fig. 9. (a) Symmetry axes of the model; (b) symmetry introduced into the model
and boundary conditions



66 J.Juraszek

In the first part of calculations (analysis of clamping) the jaw comes closer
to the element to be clamped at a very low speed, i.e. the process can be
considered as a quasi-static one. In practice, the jaws are pressed against each
other until they come into contact. In the presented scheme, this stage of the
process is denoted as ”translation”. At this stage, the initial circular shape of
the clamping sleeve changes into the shape determined by the clamping jaws.
The boundary conditions, based on the assumption of symmetry with respect
to the axes x and y aremarked as well. The next stage of the process consists
in unloading the joint through taking the jaws away down to their initial posi-
tion. The process is performed according to the unloading curve and requires
a high number of unloading steps. After completing the unloading process,
some stresses still remain in the material. They are known in the literature
as the residual stresses. These stresses, as it has been many times proved by
the author basing on his investigation results, determine the joint carrying
capacity. The carrying capacity means here the maximum force acting upon
the joint that does not cause the rope or cable to slip out of the clamping sle-
eve.Magnitudes and distributions of residual stresses, a part from offering the
possibility ofmonitoring the deformation process, provide also very important
information about the process efficiency. Figures 10a,b show exemplary octa-
gonal and dodecagonal jaws. The jaw is twisted about rope wires to achieve
themost suitable jaw-sleeve-rope configuration that ensures largermagnitudes
of residual stresses after unloading. The effect is most profitable in the case of
the dodecagonal-twisted jaw.

Fig. 10. (a) Octagonal jaw; (b) octagonal-twisted jaw

Some simulation results of the processes of clamping and unloading for a
circular jaw within the residual stress range are shown in Fig.11 and Fig.12.
During the clamping process, the material effort of the clamping sleeve re-
aches the magnitude of 300MPa, while within the sleeve-rope contact zone
it attains 500MPa. The residual stresses remain after unloading due to dif-
ferent deformability of the joint elements and different material parameters.



The clamped joints – a survey... 67

Fig. 11. Residual stresses – the process of clamping

Fig. 12. Residual stresses – the process of unloading



68 J.Juraszek

Themagnitudes of residual stresses within the contact zone take valueswithin
the range from 150 to 250MPa.
In view of the carrying capacity of the joint, distributions of stresses and

deformations over the rope-sleeve contact zone play the most important role.
To carry out the analysis within this area, mesh nodes were suitably selected.
Results are presented in the form of circle diagrams. Figure 13 presents nodal
displacements in the courses of clamping and unloading a dodecagonal jaw.
The lateral planes of jaws togetherwith their parting planes are clearly visible.

Fig. 13. Nodal displacements in the rope-sleeve contact zone during clamping
(black) and unloading (grey)

The clamping efficiency of joints clamped by octagonal and dodecagonal
jaws was compared in terms of the reduced residual stress (unloading) that
determines the joint carrying capacity (see ”- - -” lines in Fig.14). The effi-
ciency was determined by the area below the diagram or the mean value of
the reduced residual stress. For the dodecagonal joint, the mean value was
157MPa, while in the case of elliptic one – 57MPa, therefore the difference
between stressmagnitudes reached 100MPa.The dodecagonal jaw allowed for
increasing magnitudes of the residual stresses within the contact zone almost
three times.
Then, a comparison between the dodecagonal jaw twisted by 12.5 degrees

about the axis and the elliptic jaw was made. Figure 16 presents a complete
survey of the efficiency of the analysed jaws. The efficiency of joint forming
means here the magnitude of reduced residual stress. From this figure, it can
be clearly seen that higher values appeare for dodecagonal-twisted, elliptic
and circular joints. It is obvious that most uniform stress distributions can be
observed in axi-symmetrical joints. Due to technological aspects of the clam-
ping process, hexagonal joints are employedmost commonly. The efficiency is
comparable with that revealed by octagonal joints.



The clamped joints – a survey... 69

Fig. 14. Reduced residual stress in the dodecagonal clamped joint

Fig. 15. Reduced residual stress in the dodecagonal and elliptic clamped joint during
unloading

The obtained results have been experimentally verified using the
diffraction-based ”sin2(gamma)”method for stress statemeasurements at cho-
sen points of the joint. The diffraction instrumentD-8 Advancemade byBro-
ker was used for measuring the stress tensor components within the contact
zone. For example, the radial stress component of 228MPa was measured for
the axi-symmetrical joint, which agreed perfectly with the simulation results.
This new magnetic-memory method, invented by prof. A. Dubov, was veri-



70 J.Juraszek

Fig. 16. Comparison of the clamping efficiency in the considered jaws

fied as well. The main advantage of this method consists in the possibility of
making measurements both during the clamping and unloading process. The
method is based on the fact that the diffraction of magnetic field depends on
the stress distribution in the sleeve. The resulting cross-sectional distributions
of the magnetic field agreed with the stress distributions.

5. Conclusions

• The presented analysis allows for comparison of clamped jointsmade by
making use of clamping jaws of different shapes.

• Most of the uniform reduced residual stress distribution (according to
the Huber-Mises-Huncky hypothesis) is achieved in the case of axi-
symmetrical joints, the shape of which is closest to a dodecagon. In this
respect, the octagonal jaw yields most disadvantageous results, which
however can be improved by means of turning the jaw about the rope
axis by 12.5 degrees.



The clamped joints – a survey... 71

• Higher stresses appear in the course of clamping – after release of the
jaw the internal (residual) stresses take much lower values.

• The special-shape jaw brings about a relatively uniform stress distribu-
tion along the internal sleeve edge. The main advantage consists in the
largest sleeve-rope contact zone when compared to other shapes of jaws.
This influences strongly themaximum force carried by the joint. On the
other hand, it reveals some disadvantages as well – very large deforma-
tion of the external surface and very complex shape difficult to follow in
a manufacturing process.

• The proposed data base ofmaterial parameters allows for improving the
accuracy of numerical calculations.

• The presented modelling methodology of clamped joints allows for new
designs as well as for improving the existing ones.

References

1. Altenbach J., Buczkowski R., 1991, Inkrementelle Finite-ElementeModel-
lierung des 2D-Kontaktproblems,Technische Mechanik, 12, 93-106

2. Auricchio F., 2001, Three-dimensionalmodeling of shape-memorymaterials,
J. Phys., IV, 11

3. Brinson L., 1993, One dimensional constitutive behavior of shape memory
alloys, J. Intel. Mater. Syst. Struct., 4, 229-242

4. Buczkowski R., Kleiber M., 1992, Finite element analysis of elastic-plastic
plane contact problemwith nonlinear interface compliance, Journal of Theore-
tical and Applied Mechanics, 30, 4

5. Bures R., Kohutek J., 2000, IntenetoveMaterialowe Data Bazy, 9th Inter-
national Metallurgical Conference, METAL 2000

6. Dobrzański L.A., 2001, Zasady doboru materiałów inżynierskich z kartami
charakterystyk, Wyd.II,Wydawnictwo Politechniiki Śląskiej

7. Dorfmann A., Pabst O., Beh R., 1999, Combined numerical and expe-
rimental analysis of the mechanical and thermal stress distribution in rubber-
aluminiumroll,The 8TH International Congress forTransport byRopeOITAF,
San Francisco

8. Elektroenergetyczne linie napowietrzne, Elbud Kraków 1980



72 J.Juraszek

9. Hrycaj P., Cescotto S., Oudin J., 1999, Elasto-plastic finite element ana-
lysis of unilateral contact with generalized Columb friction,Engineering Com-
putations, 8, 291-303

10. Jung Y., Papadopoulos P., Ritchie R., 2002, Constitutive modelling and
numerical simulation on multivariant phase transformation in superelastic al-
loys, Int. J. Num. Meth. Engin.

11. Juraszek J., 1992, Zastępcza sztyność poprzeczna lin stalowych i przewodów
aluminiowo-stalowych, Zeszyty Naukowe Poliechniki Łódzkiej Filii w Bielsku-
Białej, 9, 53-62

12. Juraszek J., 1994,Analysis of the hexagonal clasp-joint – plastizitat,GAMM,
5.7, p.78 TUBraunschweig

13. Juraszek J., 1995, Modeling of steel ropes and steel-aluminium wires with
substitute crosswise stiffness, International Congress on Industrial and Applied
Mathematics ICIAM’95, Hamburg

14. Juraszek J., 1997, Elasto-plastic analysis of the wire, GAMM, 7, Computa-
tional Mechanics, p.48, TURegensburg

15. Juraszek J., 1999,Elasto-plastic analysis of the clasping process,Gesellschaft
für Angewandte Mathematik und Mechanik, GAMM’99, Metz

16. Juraszek J., 2000, Analysis of steel wire clamp by FEM, XI International
Wire Conference

17. Juraszek J., 2004, Method of analysis of wire clasp joint, The International
Journal of Transport and Logistics, 6

18. Kleiber M., 1984, Metoda elementów skończonych w nieliniowej mechanice
kontinuum, PWN,Warszawa

19. Kliber J., 2000, Theoretical and technological aspects of rails rolling, 9th
International Met. Conference Metal, Ostrava

20. Landre J., Pertence A., Cetlin P.R., Rodrigues J.M.C., Martins
P.A.F., 2003, On the utilisation of ductile fracture criteria in cold forging,
Finite Elements in Analysis and Desing, 39, 3

21. MacDonald B.J., Hashmi M.S.J., 2002, Shape desing sensitivity analysis
and optimization of general plane arch structures, Finite Element in Analysis
and Desing, 39, 2, 137-1653

22. Maligda J., StanovaE.,DanciM., 2000,Geometrical dresing of steel cable
using optima strands of circular cross section, Transactions of the Universites
of Kosice, 2

23. Molnar V., 2004, Computer utilization for desing of the rope constructions
andtheir strainmodeling,The International Journal of Transport andLogistics,
6



The clamped joints – a survey... 73

24. Provatidis C.G., 2003, Analysis of axisymmetric structures using Coon’s in-
terpolation, Finite Element in Analysis and Desing, 39, 5/6, 535-558

25. Stanova E., Molnar V., 2003, The steel rope and the possibilities of its
mathematical modeling,Transactions of the Uniwersities of Kosice, 3

26. TanakaK., Kobazashi S., Sato Z., 1986, Thermomechanics of transforma-
tion pseudoelasticity and shapememory effect In alloys, Int. J. of Plasticity, 2,
59-72

Złącza zaciskowe – przegląd i analiza ich kształtów oraz stosowanych
materiałów

Streszczenie

Wpracydokonanoprzeglądu stosowanychzłącz zaciskowych.Złączamają istotny
wpływ na poziom bezpieczeństwa całej konstrukcji. Przeprowadzono analizę nume-
ryczną oceniającą efektywność stosowanych kształtów połączeń zaciskanych. Zapre-
zentowano cyfrową bazę danych parametrówmateriałowych stosowanych do budowy
złącz zaciskanych.

Manuscript received March 29, 2005; accepted for print April 19, 2005