Jtam-A4.dvi


JOURNAL OF THEORETICAL

AND APPLIED MECHANICS

55, 2, pp. 461-467, Warsaw 2017
DOI: 10.15632/jtam-pl.55.2.461

ANALYSIS OF SELECTED DYNAMIC FEATURES OF

A TWO-WHEELED TRANSMISSION SYSTEM

Piotr Krawiec

Poznań University of Technology, Chair of Basics of Machine Design, Poznań, Poland

e-mail: piotr.krawiec@put.poznan.pl

Thepaperpresents results of analysis of selecteddynamic features of anuneven-running two-
-wheeled strand transmission.The characteristic features of such type of transmissions is the
ability of obtaining variable kinematic and dynamic features by the application of wheels
with a noncircular envelope. Particularly, high interest of application of uneven-running
transmissions was done in the previous century. At that time, a concept of application
of such transmissions for process and machine control was invented. The applications in
textile and engineering industry arewidely known.Amathematicalmodel of themultiplying
transmission is presented. Few versions of dynamic features of the transmission for different
loads and solid moments of inertia are examined. The presented results can be very helpful
for designers of classical and uneven-running strand transmissions.

Keywords; transmission, variable gear ratio, mathematical model

1. Introduction

The analysis of dynamic features of a strand transmission with variable gear ratio is a complex
and a nontypical process. This complexity results from the specific character of such a trans-
mission, which is determined by the shape of the toothed wheel. It is found that there is a lack
of scientific literature concerning empirical research of strand transmissions with noncircular
toothed wheels.
The author of the work (Grzelak, 2007) presented the equation of motion of a strand trans-

mission with elliptical wheels. He also estimated the influence of initial orientation and the
geometry of rotating elements on the characteristics of velocity and acceleration, which are cau-
sed by an impulse of moment that is acting on the driving wheel. This problem was solved
with the application of Matlab software. The author showed that the elliptical transmission
with identical wheels can work as a transmission with a constant or periodically variable gear
ratio. However, during the analysis of kinematics and dynamics, he did not take into account
the following condition: length of the wrap of the transmission for any angle of rotation of the
wheel must be a constant value andmust be equal to length of the standard belt.
The subject of the work by Buśkiewicz (2000) was analysis of torque transfer in the trans-

missionwith one elliptical wheel and one circular wheel, whichwas eccentric fixed.The constant
length of wrap was not kept in that transmission. The relationships between torques on driving
and driven wheels were formulated for the analysed transmission.
The study by Kelm (2006) was about the determination of differences between lengths of

driving and driven strands of the uneven-running two-wheeled transmission. The author presen-
ted the application of a pulley with a slight out-of-round in the drive of the timing gear of a
combustion engine. He showed the advantages of such a solution in comparison with a classical
strand transmission with circular wheels.
In the available literature, there is a lack of discussion about strand vibrations in uneven-

running transmissions. The studies concerning classical strand transmissions are only known



462 P. Krawiec

(Kido et al., 1994; Krasiński andStachoń, 1997, 2004;Martins andRobson, 2013). These studies
do not exhaust the topic with reference to theory of vibrations (Bajkowski, 1989; Kurnik, 1985).
However, one can findmany publications about the load capacity of transmissionswith different
types of belts (Bulushi et al., 2015; Chen et al., 1998; Jang et al., 2014; Johannesson andDistner,
2002; Korolev, 1990).
The main purpose of the application of an uneven-running transmission is not transfer of

power, but the obtaining of variable kinematic features. Therefore, forces resulting fromcontinu-
ous accelerating or decelerating ofmasses of noncircular belt pulleys have the essential influence
on the load capacity of the transmission (without external resistant torque). The goal of the
research is the determination of the influence of:

• mass moments of inertia of toothed wheels,

• values of coefficients of viscous damping,

• angular velocities of the driving shaft,

• resistant torques MOP ,

• load torques MS

on the selected dynamic features of the uneven-running transmission.
Multiplying and reduction gear are taken into account in the research.

2. The mathematical model of an uneven-running transmission

Multiplying gear are taken into account in the presented research of transmissions.
Lagrange’s equationsof the2ndtypearebasic equations for thedeterminationof the equation

of motion for the uneven-running transmission. The classical form of the equation is as follows

d

dt

(∂EK
∂u̇i

)

−

∂EK
∂ui
+
∂EP
∂ui
+
∂RR
∂u̇i
= Fi i =1,2, . . . ,n (2.1)

where EK, EP , ER are kinetic, potential and dissipation energy of the system, respectively,
u̇, u – velocities and generalized coordinates, Fi – generalized excitation.

Fig. 1. A diagram of the strand transmission with noncircular cogbelt pulleys

In the analysed transmission

EK =
1

2
J1ϕ̇
2+
1

2
J2ψ̇

2 ER =
1

2
C1ϕ̇

2+
1

2
C2ψ̇

2

and EP =0 – assumption: the strand is inextensible.



Analysis of selected dynamic features of a two-wheeled transmission system 463

After determining components of the energy and substituting these components to equation
(2.1), the following form of the equation of motion for the strand transmission – multiplying
gear (Fig. 1) has been obtained

J1ϕ̈+J2ϕ̈
∂ψ

∂ϕ
+J2ψ

d

dt

∂ψ

∂ϕ
+C1ϕ̇+C2ψ̇

∂ψ

∂ϕ
= MS −MOP

∂ψ

∂ϕ
(2.2)

where J1, J2 are reducedmass moments of inertia for the driving and driven wheels and shafts,
respectively, ϕ – angle of rotation of the drivingwheel, ψ – angle of rotation of the drivenwheel,
C1, C2 – coefficients of viscous damping in the bearings of driving and driven shafts, MS – load
torque of the driving wheel, MOP – resistance torque.
It is assumed that the transmission will be loaded with a constant resistance torque which

is defined as

MOP = MOPmax(1− e
−αϕ̇) (2.3)

In order to solve equation (2.2), one should determine the relationship ψ = f(ϕ), which
describes the change of the angle of rotation of the driven wheel in function of the angle of
rotation of the driving wheel. The mean square trigonometric polynomial of the 6th degree is
used for description of this relationship

ψ = aϕ+ bsin(2ϕ)+ csin(2ϕ)+dcos(4ϕ)+esin(4ϕ)+f cos(6ϕ)+ . . .+g(6ϕ)

The time derivative of the angle of rotation of the driven wheel (velocity) is determined as

ψ̇ =
dψ

dt
= aϕ̇−2bsin(2ϕ)ϕ̇+2ccos(2ϕ)ϕ̇−4dsin(4ϕ)ϕ̇

+ . . .+4ecos(4ϕ)ϕ̇−6f sin(6ϕ)ϕ̇−6gcos(6ϕ)ϕ̇ = ϕ̇
∂ψ

∂ϕ

(2.4)

that is

ψ̇ = ϕ̇
dψ

dt

The second time derivative of the angle of rotation of the driven wheel is determined as
follows (acceleration)

ψ̈ =
dψ̇

dt
= aϕ̈−2b2cos(2ϕ)ϕ̇2−2bsin(2ϕ)ϕ̈−2 ·2csin(2ϕ)ϕ̇2

+ . . .+2ccos(2ϕ)ϕ̈−4 ·4dcos(4ϕ)ϕ̇2 −4dsin(4ϕ)ϕ̈−4 ·4dcos(4ϕ)ϕ̇2

− . . .−4ecos(4ϕ)ϕ̈−6 ·6f cos(6ϕ)ϕ̇2 −6f sin(6ϕ)ϕ−6 ·6g sin(6ϕ)ϕ̇2 +6gcos(6ϕ)ϕ̈

For simplification of the record, the following denotation is taken into consideration:
dψ/dϕ = CM, where the index M denotes the multiplying gear

dψ

dϕ
= a−2bsin(2ϕ)+2ccos(2ϕ)−4dsin(4ϕ)+4ecos(4ϕ)−6f sin(6ϕ)−. . .−6gcos(6ϕ) = CM

(2.5)

while

d2ψ̇

dϕ̇2
=

d

dϕ

(dψ

dϕ

)

=−4bcos(2ϕ)−4csin(2ϕ)−16dcos(4ϕ)−16esin(4ϕ)

− . . .−36f cos(6ϕ)−36g sin(6ϕ) =−BM



464 P. Krawiec

The following relationship is determined as the last one

d

dt

(dψ̇

dϕ̇

)

=−4bcos(2ϕ)ϕ̇−4csin(2ϕ)ϕ̇−16dcos(4ϕ)ϕ̇−16esin(4ϕ)ϕ̇

− . . .−36f cos(6ϕ)ϕ−36g sin(6ϕ)ϕ̇

(2.6)

For simplification of the record, the following denotation is taken into consideration:

BMϕ̇ =4bcos(2ϕ)ϕ̇+4csin(2ϕ)ϕ̇+16dcos(4ϕ)ϕ̇+16esin(4ϕ)ϕ̇

+ . . .+36f cos(6ϕ)ϕ̇+36g sin(6ϕ)ϕ̇

On the basis of relationships (2.4)-(2.7) and proper substitutions, the following form of
equation (2.2) is obtained for the multiplying gear

J1ϕ̈+J2ϕ̈
(∂ψ

∂ϕ

)2
−C2M −J2ϕ̇

2CMBMϕ̇+C1ϕ̇+C2ϕ̇(CM)
2 = MS −MOPCM (2.7)

and finally

ϕ̈ =
(MS +2BMCMJ2)ϕ̇

2
− (C1+C2C

2
M)ϕ̇

J1+J2C
2
M

(2.8)

3. Results of numerical calculations

A few variants of the dynamics of the two-wheeled uneven-running transmission for different
values of load andmassmoments of inertia are analysed below. In order to improve calculations,
computer programUneven-running strand transmission –Dynamics, NPC-Dhas been designed.
This program has been written in Visual Basic. The constant step of integration with the value
of 0.001s has been assumed in calculations. The task has been solvedwith the use of theRunge-
-Kutta method of the 4th order.
At first, themultiplying gearwith constant values of the kinematic excitation (ω1 =40rad/s)

and with the following data: J1 = 0.06kg·m
2, J2 = 0.01kg·m

2, C1 = 0N·m·s, C2 = 0N·m·s,
MS =0N·m,MOP =0N·m(Figs. 2 and 3) has been analysed. In order to simplify description of
the axis in graphs, the following denotations are taken into consideration: ω – angular velocity,
a – acceleration.

Fig. 2. Velocity of wheel 1 and 2 in function of time (ω1 =40rad/s)

Next figures (Figs. 4 and 5) present characteristics of velocity and acceleration of the ge-
ar wheels of the multiplying gear with the following values: ω1 = 1rad/s, J1 = 0.06kg·m

2,
J2 =0.01kg·m

2, C1 =0.002N·m·s, C2 =0.01N·m·s, MS =0.1N·m, MOP =0N·m.



Analysis of selected dynamic features of a two-wheeled transmission system 465

Fig. 3. Acceleration of wheel 1 and 2 in function of time (ω1 =40rad/s)

Fig. 4. Velocity of wheel 1 and 2 in function of time (ω1 =1rad/s)

Fig. 5. Acceleration of wheel 1 and 2 in function of time (ω1 =1rad/s)

Figures 6 and 7 illustrate characteristics of the change in velocity and acceleration of the
gear wheels of the multiplying gear for the following data: J1 = 0.3kg·m

2, J2 = 0.3kg·m
2,

C1 =0.02N·m·s, C2 =0.02N·m·s, MOP =4N·m, MS =9N·m.



466 P. Krawiec

Fig. 6. Velocity of wheel 1 and 2 in function of time (ω1 =20rad/s)

Fig. 7. Acceleration of wheel 1 and 2 in function of time (ω1 =20rad/s)

4. Summary

On the basis of the determined characteristics of the mathematical model of the transmission,
one can draw the following conclusions and observations:

• Considerable accelerations of the driven wheels occur for low values of mass moments of
inertia and for relatively high values of velocities.

• Constant gear ratio and constant accelerations can be obtained when the dimensions
(mass) of the gear wheels are great.

• The transmission can not work with a too high rotational speed.

• In the case of multiplying gear with the following values of mass moments of inertia:
J1 = 0.06kg·m

2 and J2 = 0.01kg·m
2, without the external load and on the assumption

that frictional resistance is neglected; one can observe (during kinematic excitation) that
the velocity of the driving wheel is characterized by considerable variability for a quasi-
-constant velocity of the driven wheel. In the range of velocity from 10rad/s to 40rad/s,
the acceleration of the drivenwheel is 15 times higher than the acceleration of the driving
wheel.

• For themultiplying gearwith the considered conditions: viscosity friction, small torqueMS
andno resistance torque; the characteristics of rotational speedandacceleration are similar
but their amplitudes are different, and the acceleration of wheel 1 is higher than the
acceleration of wheel 2.



Analysis of selected dynamic features of a two-wheeled transmission system 467

• The resistance torquewhich is placed in the description of the analysed transmission, does
not cause any changes to the characteristics of velocity and acceleration. However, in this
case, the acceleration of the driven wheel is higher than the acceleration of the driving
wheel.

• Equal and relatively small values of mass moments of inertia for both wheels and the
following assumptions: no frictional resistance and no loads; lead to higher amplitudes of
velocity and acceleration in comparison with transmissions with different mass moments
of inertia.

References

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Manuscript received June 20, 2016; accepted for print September 16, 2016