JOURNAL OF THEORETICAL

AND APPLIED MECHANICS

43, 4, pp. 893-907, Warsaw 2005

STRENGTH ANALYSIS OF A MULTI-CLIP JOINT

Janusz Juraszek

Department of Mechanical Engineering Fundamentals, University of Bielsko-Biała

e-mail: jjuraszek@ath.bielsko.pl

The paper is concerned with strength analysis of multi-clip joints. Such
structures enable visible growth of the carrying capacity andmake them
elements easily assembledby the clamping jawsanda single-clamppress.
Each joint exerts an appreciable influence upon the safety level of the
whole structure. A numerical analysis was performed to assess the effect
of clearance between a sleeve and rope upon the joint quality. Phenome-
na emerging in the area between the clips were analysed as well. Some
strength tests related to the process of drawing the wire rope out of the
sleeve were also investigated. Changes in the stiffness of the clamping
sleeve were analysed in view of the influence of the aforementioned fac-
tors upon the carrying capacity of joints and the sleeve material effort.
Experimental investigationswere conducted aswell aiming at the deter-
mination of the smallest possible number of clips or the effective length
of joints necessary for carrying the loads higher than the admissible load
of the wire rope.

Key words: multi-clip joint, shapes, jaw, FEM

1. Introduction

The applicability of a single-clip joint is limited by a size of an available
press performing a clamping process. Usually, such presses have a carrying
capacity of 1000KN and allow the clip width to range between 15-20mm in
the case of steel sleeves (grade 10) and between 35-50mm for a sleeve made
of A0 aluminium. To arrive at a higher load carrying capacity of the joint, a
number of clips made with a circular pitch t can be produced; such a joint
is called the multi-clip one (see Fig.1). A clear advantage the joint can offer
consists in a higher carrying capacity with no need for special equipment; i.e.
using the same clamping press and clamping jaw. That is very important in



894 J.Juraszek

view of technological and economic aspects of the manufacturing process. On
the other hand, to make a single clip joint of a sufficient length one should
have a press of much higher load carrying capacity at his disposal.

Fig. 1. Multi-clip joint

Such a press, of course, would bemuchheavier and larger,making outdoor
applications very difficult. This aspect is very important in the case of moun-
ting of power transmission lines, where two workers should be able to carry
the press over.
Themulti-clip joints, classified as permanent ones, are often used for con-

necting and fixing steel wire ropes (hereinafter the term ”rope” is used), elec-
tric cables or hydraulic conduits. The clamping process consists in making
clips one by one, and after each clamping process the unloading takes place.
Hankus (1988, 1990) showed mechanical properties of ropes determined

in the rope axis direction, while Brzoska et al. (1982) examined the proper-
ties they reveal in the transverse direction. In the papers by Juraszek (1992,
1993, 1999), the authors put forward the concept of equivalent transversal
stiffness and determined transversal deformability of ropes and electric ca-
bles. The problem of mounting durability, when a rope is fixed in a thimble
(temporary joint), was presented byCarbogno (1988), Carbogno et al. (1998),
Wójcik and Rokita (1998) determined the true load acting upon a rope of a
cable railway, which is very important in view of technological aspects and
crucial for a proper choice of the joint type for rope fixing. For more details
of technological and operational aspects of the problem the Reader is refer-
red to the journal ”International Rope Review” (in German, Internationale
Seilbahn-Rundschau).
This paper presents an attempt to analyse phenomena appearing between

clips as well as to study the process of drawing a rope out of the sleeve (si-
mulating that way true working conditions of a joint). The influence of the
stiffness of a clamping sleeve upon the joint carrying capacity is also assessed.
Based upon research results, the effect of the sleeve-to-rope clearance (intro-
duced due to the mounting reasons, therefore hereinafter it bears the name
”mounting clearance”) upon residual stress is found. Owing to that, the load
carrying capacity of the joint can be determined.



Strength analysis of a multi-clip joint 895

2. Models of the multi-clip joint

The phenomena occurring between particular clips have been analysed in
an axi-symmetrical clamped joint. Basing on the research presented in Jura-
szek (1992, 2002, 2004), the Author applied a rope model in the form of a
sleeve which enabled him to find the equivalent transversal stiffness chosen
suitably on investigations of the true rope stiffness. Thus, the deformability of
a rope within its contact zone with a clamping sleeve remained unchanged in
the model.

Fig. 2. Scheme of the necessarymounting clearance

The geometrical model was constructed basing on an engineering speci-
fication of a multi-clip joint. The element of the plane 42 type was applied,
supplied with the option of axi-symmetrical analysis. In themodel, there was
a mounting clearance of 0.05mm introduced between the sleeve and the rope
(i.e. the internal diameter of the sleeve was higher by 0.05 than the nominal
diameter of the rope – see Fig.2.). Then amodel of the contact zonewas built
using elements of the typeContact 48. The boundary conditions resulted from
the assumedaxial symmetry of the problem.The axis of symmetry of the joint
overlapped the y-axis. At the next stage, the clamping process was performed
involving jaws 1,2,3 (see Fig.3.) in the consecutive way.

Then the phenomena emerging when the ropewas drawn out of the sleeve
were analysed. The process of drawing out was divided into stages determined
by lengths of rope segments drawn out of the joint each time. The effort of the
sleevematerial was analysed in terms of the reduced stress and stress intensity.
The resultsweremeasured at selected cross-sections between clips 1-2 and2-3.

Another model was also created that allowed for introduction of variable
stiffness of the clamping sleeve. The size of a clamping sleeve (external diame-
ter) was chosen basing on the condition that the rope and sleeve exhibit the



896 J.Juraszek

Fig. 3. Scheme of the mounting process

same strength. The working principle of the multi-clip joint is based on the
assumption that each subsequent clip ”transmits” a higher load from the rope
to the sleeve than the previous one. At the initial stage of the load transmis-
sion, the sleeve deforms only slightly as compared to the rope which carries
almost the whole load. The differences in the deformability of the rope and
sleeve, respectively,may force those two elements to translate onewith respect
another which is definitely a disadvantageous phenomenon. A scheme of the
variable-diameter joint is shown in Fig.4.

Fig. 4. Joint with a step-wise external diameter

3. Theoretical background

The theoretical background of themethod is presented below. Changes in
material parameters in the course of the deformation process are taken into
account. The Amont-Coulob fricton model is introduced into the sleeve-rope



Strength analysis of a multi-clip joint 897

contact area. The clamping process is assumed as a quasi-static one. AnFEM
approach assists the analysis of the plastic deformation problem.

The equation of equilibrium for amedium can be derived from the virtual
work principle (Kleiber, 1984). In the case of a general Lagrange’s formulation
we have ∫

V

Sij δεij 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

p δUk dA+

∫

V

f δUk dV (3.2)

The above equation has been derived on the assumption that the body confi-
guration 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 sur-
face andvolume forces acting upon a unit surface andunit volume of the body
corresponding to the initial configuration. δUk represents the displacement
variation, while δeij stand for the strain variations

δeij = δ
1

2
(kUi,j + kUj,i) (3.3)

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

k
K
k
U = k+1R− kF (3.4)

where
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.

Throughout considerations the term ”step”means subsequent incremental
loading steps.



898 J.Juraszek

4. Results of numerical simulation

Some primary analyses of the mounting clearance effect upon the magni-
tudes of residual stresses have been conducted using amodel with a clearance
of 0.05 mm, hereinafter called the basic model.
The computations have been made for the basic model. Other variants,

differing in the clearance size are presented in Table 1.

Table 1.Different sizes of the mounting clearance

Variant number Clearance size s [mm]

var1 0.01

var2 (the basic one) 0.05

var3 0.35

var4 0.65

var5 0.95

var6 1.25

var7 1.55

Sample simulation results obtained for the basic joint in terms of the ma-
gnitudes of radial stresses Sx aswell as of those acting along the joint axis SY
after the clamping process has been completed are presented in Fig.5 and
Fig.6.

Fig. 5. Sx stress in the basic variant of the joint



Strength analysis of a multi-clip joint 899

Fig. 6. Sy stress in the basic variant of the joint

Fig. 7. The effect of clearance size upon the stress Sx

The calculations made for the other 6 variants are presented in Table 1.
Figure 7 shows the results of comparison between the magnitudes of radial
stresses Sx obtained for different variants, depending on the clearance size. It
canbe clearly seen in this figure thatwhen the clearance grows, themagnitude



900 J.Juraszek

of radial stress decreases within the contact zone. That involves the reduction
in the carrying capacity of theaxial load (Juraszek, 1999).Wearrive, therefore,
at the conclusion that the smallest possible clearance between the rope and
sleeve should be ensured.

The way the joint works has been analysed focusing on the phenomena
emerging between particular joints. A scheme of the rope drawing out of the
sleeve is shown in Fig.3. From the results of FEM computations, those obta-
ined in the most interesting cross-sections have been selected (see Fig.8).

Fig. 8. Considered cross-sections

The true working conditions of the joint have been simulated when the
ropewas drawn out of the sleeve. Figures 9 and 10 present thematerial efforts
obtained in the consideredcross-sections.Thehigher level of thematerial effort
observed in the first cross-section should be emphasized.

Next the joint with a step-wise external diameter was analysed. The follo-
wing assumptions were accepted:

• Material parameters of the model are non-linear

• FEM mesh is similar to that used in the basic model

• Boundary conditions, loading and unloading processes are the same as
in the case of the basic model.

It is well known that the sleeve-rope contact zone determines the joint
carrying capacity. Therefore, to make the simulationsmore precise, the nodes
lying in this area were selected using the ANSYS code options.



Strength analysis of a multi-clip joint 901

Fig. 9. Material effort SEQV in the first I-I cross-section

Fig. 10.Material effort SEQV in the second II-II cross-sections

In Fig.11, numbers of the selected nodes 0-120 (or their abscissas) are
marked along x-axis. The node selection has beenmade also in the two cross-
sections - between clips 1-2 and 2-3 in the direction perpendicular to the joint
axis.



902 J.Juraszek

Fig. 11. Sx stress in the basic joint and in the joint with the variable external
diameter

Due to a step-wise size of the external diameter, the magnitudes of the
radial stress Sx in the first clip are reduced, while in the second and third
clips they rise gradually (see Fig.11).

Fig. 12. Sy stress in the basic and variable-diameter joints

Since the diameter is smaller, the Sy stress (in the direction of the joint
axis) between the clips x-x are almost twice as much as in the joint of the
constant diameter (see Fig.12). In the second cross-section, the radial stress



Strength analysis of a multi-clip joint 903

increases three times. In view of the joint working quality, one should consider
the increase of the radial stress as an advantageous effect since smaller diffe-
rences in the deformability of the rope and sleeve are involved in particular
cross-sections between the clips. From the analysis of stress intensities obta-
ined for different models, it can be concluded that the material effort in the
joint with a step-wise diameter is lower as compared to the standard joint of
the same carrying capacity. The effect of the sleeve wall thickness variability
introduced by a step-wise change in the external diameter of the clamping
sleeve from 56mm to 47mm and in other diameters (b and c) is shown in
Fig.13.

Fig. 13. Variability of the sleeve wall thickness

Table 2

Variant Diameter Diameter Diameter
number a [mm] b [mm] c [mm]

var1 56.0 48.0 40.0

var2 54.2 46.8 39.4

var3 52.4 45.6 38.8

var4 50.6 44.4 38.2

var5 48.8 43.2 37.6

var6 47.0 42.0 37.0

All other parameters of the process remained unchanged. Further decre-
ase in the external diameter involves reduction in the Sx stress (see Fig.14)
accompaniedby simultaneous growth in themagnitudeof the Sy stress.There-
fore, through changing of the diameter of the clamping sleeve, one can improve
the sleeve deformability so that it can better adapt to the rope deformability
between the clips.



904 J.Juraszek

Fig. 14. Courses of the Sx stress in different variants of the joint geometry

5. Experimental investigations

Multi-clip joints with the rope diameters assuming valueswithin the range
from 12 to 42mm were examined. A joint was classified as properly chosen
if its tensile strength was higher than the rope breaking strength, i.e. when
the rope broke outside the joint area. The internal diameter of the clamping
sleeve was equal to 1.02 of the rope nominal diameter. The clearance size of
2% of the rope nominal diameter allows the rope tip to be inserted into the
sleeve with no additional equipment needed. Since from the clearance analysis
it followed that the smallest possible clearance size is themost profitable one,
the value of 2% of the rope nominal diameter could be accepted. The external
diameter of the clamping sleeve Dz is chosen for each rope diameter upon
the assumption that the rope and sleeve reveal the same tensile strength. The
experimental verification consisted in the determination of the joint carrying
capacity, i.e. the highest load the joint can carry without translation of the
rope relative to the sleeve. According to the frictional hypothesis of the jo-
int carrying capacity, this quantity is a function of the residual stress on the
rope-sleeve contact surface. A special test stand was built to determine the
carrying capacity of the joint. Axial displacements of the rope weremeasured
at 4 points. The design of the test stand allowed formeasurements of the rope
translation relative to the fixed clamping sleeve. For the measurement purpo-
ses, three inductive sensors were employed as well as a mechanical inductor



Strength analysis of a multi-clip joint 905

for control purposes. General test results showed the shortest possible length
along which the clamping process should be performed for the resulting joint
carrying capacity to be at least equal to the rope carrying capacity (admissible
load).

Fig. 15. The number needed of clips as a function of the rope diameter

6. Conclusions

The results of numerical simulations prove that the smallest possible cle-
arance between the rope and sleeve should be aimed at. Technological aspects
of the joint mounting process determine the lower limit of the clearance size.
In practice, the smallest possible value of the diameter of the sleeve should
be equal to 1.02 of the nominal rope diameter which allows for straightfor-
wardmounting (insertion) of the rope into the sleeve. Clamped joints are very
simple from the technological point of view and reveal small external sizes
as compared to joints commonly used at present. The aforementioned results
of theoretical and experimental investigations can be used in formulation of
structural and technological suggestions concerning the development of new
jointdesigns.A step-wise change in the transversal stiffness improves quality of
the joint. The considered joints exhibit a relatively lowmaterial consumption
index.
In the near future, clamped joints will be applied to mounting of control

andmeasurement cables. The presentednumericalmodel allows for shortening



906 J.Juraszek

of the calculation time by almost 70% as compared to the 3Dmodel presented
in Juraszek (2004). The results obtained from those two models differ by 5%.
From the investigations conducted, two important factors that determine the
joint quality; i.e. the required joint length and the number of needed clips, can
be found as well.

References

1. Brzoska Z., Adamiec L., Jędrzejczyk R., 1982, Badania odkształcalno-
ści lin stalowych, X Sympozjum Doświadczalnych Badań w Mechanice Ciała
Stałego, Warszawa, 60-65

2. CarbognoA., 1998,Fatigue failure of hosting ropes in to the cage susupension
gear, 10th International Conference IPUSR, 138-144

3. Carbogno A., Mender A., Krawczyk J., 1998, Durability of guide ropes,
10th International Conference IPUSR, 154-160

4. Hankus J., 1998,Współczynnik sprężystości lin stalowych. Część I, Przegląd
Mechaniczny, 15

5. Hankus J., 1990,Budowa i własności lin stalowych, Wyd.1. Katowice GIG

6. Juraszek J., 1992,Zastępcza sztywnośćpoprzeczna lin stalowych i przewodów
aluminiowo- stalowych, Zeszyty Naukowe Politechniki Łódzkiej Filii w Bielsku-
Białej, 9, 53-62

7. Juraszek J., 1993, Analysis of the multiple clasp-joint, Gesellschaft für An-
gewandte Mathematik und Mechanik GAMM, 2, p.112, TUDresden

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

9. Juraszek J., 2002, Data base of material parameters for analysis forming
process by FEM, Int. Conf. Metal., 127, 2

10. JuraszekJ., 2004,Methodof analysiswireclasp joint,Transport andLogistics,
6, 157-163

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

12. Wójcik M., Rokita T., 1998: Analysis of actual loads in haul rope of the
bicale aerial ropeway, 10th International Conference IPUSR, 222-228



Strength analysis of a multi-clip joint 907

Analiza złącza wielozaciskowego

Streszczenie

W pracy przeprowadzono analizę złącz wielozaciskowych. Umożliwiają one osią-
gnięcie większej nośności złącza poprzez zastosowanie szczęk zaciskających i prasy do
zacisków jednokrotnych. Złączamają istotny wpływ na poziom bezpieczeństwa całej
konstrukcji, w której są zainstalowane. Przeprowadzono analizę numeryczną ocenia-
jącą wpływwielkości luzu między tuleją a liną, analizę zjawisk zachodzącychmiędzy
poszczególnymi zaciskami, analizę procesu wyciągania liny oraz zmiany sztywności
tulei zaciskanej.Wykonane następnie badania doświadczalne umożliwiływyznaczenie
najmniejszej liczby zacisków lub długości efektywnej złącza niezbędnej do przeniesie-
nia obciążenia większego od nominalnego obciążenia lin.

Manuscript received May 19, 2005; accepted for print July 11, 2005