Jtam-A4.dvi


JOURNAL OF THEORETICAL

AND APPLIED MECHANICS

54, 4, pp. 1169-1181, Warsaw 2016
DOI: 10.15632/jtam-pl.54.4.1169

LOAD DISTRIBUTION IN THE WORM MESHING

Henryk G. Sabiniak

Technical University of Lodz, Łódź, Poland

e-mail: henryk.sabiniak@p.lodz.pl

The paper presents a theoretical analysis of deflections of circular and rectangular cantilever
plates of an elastically built-in edge. The problemhas been solved using the finite difference
method.Amethod of determination of loaddistribution between twoplates being in contact
along anarbitrary line has beenpresented.Different shapes of these plates constitutemodels
of mating of cylindrical and globoidal worm meshings. To verify the presented theory of
searching for load distributions along the contact lines in these meshings, experimental
investigationswith the freezing of stresses in the cylindricalwormmeshinghavebeen carried
out. Directions of investigations that would specify further theoretical considerations over
load distribution in globoidal gear meshings have been indicated.

Keywords: finite differences, circular plate, cantilever plates, worm teeth, load distribution

Notations

A – distance of axes, auxiliary constant

D – binding rigidity of plate

E,ν – Young’s modulus and Poisson’s ratio

F,Fi – force and force acting at point i of contact line, respectively

F1i (ri,ϕi),F
2
i (ri,ϕi) – force acting at point i of contact line of plate 1 and 2, respectively

Fw – inter tooth force

Kri,ϕir,ϕ – dimensionless parameter of deflection of plate

R,Rn –minimum andmaximum radius of the plate, respectively

Rz – radius of tooth tips of wormwheel

h – plate thickness

m – module

p – screw parameter

q – linear load

r – average radius of circular cantilever plates

rg – radius of globoid of wormwheel

rn – radius of cylinder pitch of worm

z1 – number of teeth of worm

(r,ϕ),(ri,θ,z),(x,y,z) – polar, cylindrical and rectangular coordinates, respectively

αn – pressure angle

β – angle between contact line and rubbing speed vector

ϕ1 – angle of rotation of worm

ω – deflection



1170 H.G. Sabiniak

ω0(r,ϕ),ω
1
0(r,ϕ),ω

2
0(r,ϕ) – deflection at point of coordinates (r,ϕ) corresponding to total load

acting on plate, plate 1 and plate 2, respectively

ωi(r,ϕ) – deflection at point of coordinates (r,ϕ) caused by concentrated forceFi(ri,ϕi) acting
on plate

Indices: I,II,III – numbers of the contact lines.

1. Introduction

The compactness of construction, silent running and the possibility of obtaining a large trans-
mission ratio on one stage, cause theworm gears to be one of themost popular types of toothed
gears.
At the stage of designing cylindrical and globoidal worm gears, there are actually two pro-

blems to be dealt with: rubbing speed and load distribution in the meshing.
Great rubbing speeds in themeshing are characteristic forworm gears. This is their negative

feature, since they are the source of power losses which, in turn, change into heat during the
operation of the gear. This problem is well-known to the constructors of worm gears who can
lessen this negative effect while designing by a proper selection of tooth profile geometry, a shift
in the profile and the selection of material (Buckingham, 1960; Niemann and Winter, 1983;
Crosher, 2002; Dudás, 2005).
On the other hand, load distribution in the worm gear meshing can be considered unknown

or hardly known. The knowledge of distribution of load along the contact lines of the mating
teeth and the related distributionof stresses in the tooth foot, aswell as of the laws governing the
abovewill enable one – through constructional procedures at the design stage – to obtain such a
distribution of load that will allow increasing the durability of the meshing or its load-carrying
capacity.
Thewidespreaduseof rectangular andcircular cantilever plates inmachines and structuresas

their real elements, or asphysical-mathematicalmodelsof real systems,makes itnecessary for the
designer to become better-acquainted with the deformability of cantilever plates replacing real
fragments of machine parts. The present work aims at solving a number of problems concerning
the cantilever plate theory, with the special question being their adaptation to globoidal and
cylindrical wormmeshings.

2. The basics of the worm meshing theory

The external surface (tip diameter) of the worm and the surface of the globoid and the external
(maximum) diameter of the wormwheel interpenetrate and define the area in which themating
of the worm teeth and the worm wheel takes place. The determination of the area of mating
and the contact line will be presented basing on the simplest example from the point of view
of meshing geometry, namely for the gear with a worm of the profile of Archimedes teeth.
Archimedes worms are characterized by a rectilinear profile in the axial section, while the front
section of these worms is in the shape of the Archimedes spiral.
The geometry of such a wormmeshing can be described by the formulae (Litwin, 1959)

[p(Θ−ϕ1)−ri tanαn]
(

cosΘtanαn+
psinΘ

ri

)

−ricosΘ= rn

x= ri sinΘ y= ricosΘ z= p(Θ−ϕ1)−ri tanαn p=
mz1

2

(2.1)

If ϕ1 = const, then equations (2.1) define instantaneous contact lines for a given angle of
rotation of the worm.The contact between theworm teeth and the wormwheel for a given gear



Load distribution in the worm meshing 1171

takes place only in the area common for both these elements. This area is referred to as a tooth
contact area (mashing area). In other words, the tooth contact area (Fig. 1) is a working part
of the meshing area limited by the above-mentioned areas of the worm pair (Fig. 1) (Sabiniak,
1996); namely:

• the apex diameter of the worm dz (curve a),

• the globoidal area of the wormwheel with the radius rg corresponding to it (curve b),

• the maximum diameter of the wormwheelRz (curve c).

Fig. 1. The area of meshing of the worm pair: (a) in the front section, (b) in the horizontal projection

To define the tooth contact area, one must determine:

• curve a (Fig. 1), assuming ri = rg in equations (2.1), i.e. replace an arbitrary radius of the
cylinder with the external radius of the worm,

• curve b; then in equations (2.1) onemust substitute ri = rg, and add the globoid equation

(x+A)2−
(

A−
√

r2g −y
2
)2
+z2 =0 (2.2)

• curve c, by considering simultaneously equations (2.1) and the equation of the external
cylinder of the wormwheel

z2+(A+ricosΘ)
2 =R2z (2.3)

The tooth contact area and the course of the contact lines for the established value of the
angle ϕ1 is shown, by way of example, in Fig. 1 (Sabiniak, 1996).

3. The characteristics of the contact lines in the worm meshing

The course of the contact lines in the tooth contact area has a significant effect on the operating
parameters of the gear.
Modern tendencies in the construction of worm gears aim at finding such a position for the

contact lines as to let angle β, which they form with the vector of the rubbing speed (Fig. 2),
approach 90◦. Favorable conditions are then created for the formation of an oil film, and the
amount of heat in the mashing is simultaneously reduced. In addition, the shape of the contact
lines has a decisive effect on the load distribution (which will be presented further). In turn,
the course of the contact line largely depends on the profile of the mating surfaces of the teeth
and the worm wheel addendum modification coefficient. In principle, there are two groups of
profiles:

• rectilinear profiles,

• curvilinear profiles.



1172 H.G. Sabiniak

The first group comprises all worms made using a rotational tool of a rectilinear profile or
those that have a straight line in any section. The following profiles can be distinguished here:

• Archimedes profiles,

• rectilinear in the section perpendicular to the helix on the tooth reference cylinder,

• evolvent,

• conoidal.

Fig. 2. The course of the contact lines and values of the angle in gears with the following worms:
(a) cylindrical of the profile of Archimedes teeth, (b) cylindrical of the evolvent teeth profile,

(c) cylindrical of the circular-concave teeth profile, (d) cylindrical of the circular-convex teeth profile,
(e) globoidal

The contact of the teeth of the worm and the worm wheel in the gears with a rectilinear
worm is a contact of two convex surfaces, which results in the formation of great inter tooth
pressures. Then, small equivalent radii of the curvatures of the profiles along the contact line
occur.
In the group of curvilinear profiles, the following worms can be distinguished:

• of a circular-concave profile in the axial section, Cavex,

• of a circular-convex profile in the axial section.

Of the profiles discussed so far, worm gears with a globoidal worm (Fig. 2e) have the best
conditions for the formation of an oil film. Moreover, at least one more pair of teeth mates in
the case of cylindrical worm gears. The technology of making globoidal worms requires making
use of specialmachines. They are also troublesome to check. However, their operating properties
are superior to all the ones discussed hitherto.

4. Load distribution along the contact line in the worm meshing

While solving the problem of load distribution along the contact lines in the worm meshing, it
has been assumed that the tooth of the worm or the worm wheel is a cantilever plate having
one edge built-in elastically (Sabiniak, 1992). The bar between the plates illustrates the contact
line and ensures the transfer of load from one plate – a tooth – to another along the contact line
required (Figs. 3a and 3b).



Load distribution in the worm meshing 1173

Fig. 3. (a) Themodel of meshing of the globoidal worm gear: 1 – tooth of the cylindrical wheel, 2 – bar
illustrating the contact line, 3 – worm tooth; (b) the model of meshing of the cylindrical worm gear:

1 – wormwheel tooth, 2 – bar illustrating the contact line, 3 – worm tooth

Prior to the determination of load distribution, the question of deformability of the plate,
depending on its geometric parameters and material constants, has been solved by forming
matrices of rigidity of the plates (Sabiniak, 1982, 1992). Calculations of the strains (or more
precisely, of the dimensionless parameters of deflection of the plate Kri,ϕir,ϕ ) have beenmade for
each type of the plate (circular cantilever plate and a circular plate in the shape of a circular
sector) by applying the concentrated force to appropriately selected places. These appropriately
selected places are nodes of the net superimposed on the plates, through which contact lines
pass.

Basing on these results, one could start searching for load distribution along the contact line
(Fig 3 and 4), assuming at the same time that:

• the continuous loadwill be replacedwith a number of concentrated forces (Sabiniak, 1992;
Umezawa et al., 1969; Jaramillo, 1950)

Fi =

li
∫

li−1

q dl (4.1)

• the total strain of the plate is a superposition of the previously obtained deflections from
particular, independently acting concentrated forces (Sabiniak, 2012; Sabiniak and Woź-
niak, 1988)

ω0(r,ϕ) =
i=n
∑

i=1

ω(ri,ϕi) (4.2)

• the algebraic sum of deflections of both plates along the contact line is a constant value

ω10(r,ϕ)+ω
2
0(r,ϕ) =ω= const (4.3)

• the forces of reciprocal interaction in the corresponding points along the contact line of
both plates are equal to each other

F1i (ri,ϕi)=F
2
i (ri,ϕi) (4.4)



1174 H.G. Sabiniak

• the sum of forces acting in particular nodes of the contact line must be equal to the inter
tooth force

Fw =
i=n
∑

i=1

Fi(ri,ϕi) (4.5)

5. The mating of circular cantilever plates and those in the shape of the circular

sector

The deflection of the plate at the point of coordinates (r,ϕ), caused by the action of the con-
centrated force applied at the point of coordinates (r,ϕ), has the form

ωi(r,ϕ) =
h2

πD
Kri,ϕir,ϕ Fi(ri,ϕi) (5.1)

where Kri,ϕir,ϕ = f(R,R1,Rn,E,F,Fi,Fw,h,ri,v,ϕ,ϕi) have been taken from work (Sabiniak,
1992; Umezawa et al., 1969; Jaramillo, 1950).
The total deflectionof theplate at thepointof coordinates (r,ϕ)will be the sumofdeflections

from particular forces acting on the plate

ω0(r,ϕ) =
h2

πD

i=n
∑

i=1

Kri,ϕir,ϕ Fi(ri,ϕi) (5.2)

When the contact lines do not pass exactly through the nodes of the net, interpolation is perfor-
med. If the point of the contact line, e.g.K (Fig. 4) is on the line of the net between two nodes,
them the dimensionless parameter of deflection of the plate KK for such a point is determined
from the dependenceKK = a2KA+a1KB, where a1+a2 =1. If the point of the contact lineL
is not on any line of the net (Fig. 4), then the dimensionless parameter of deflection of the plate
of such a point is determined from the dependenceKL = c2(b2KE+b1KD)+c1(b2KB+b1KC),
assuming that b1+b2 = c1+ c2 =1.

Fig. 4. The interpolation of the deflections of the plate points that do not coincide with the nodes

For the dimensionless parameters of deflections of the plate in particular points of the line of
contact (5.2) thus calculated, condition (4.3) can be employed. If the number of the concentrated
forces replacing the constant load, equal to the nodes lying on the contact line is i, then –
following the application of condition (4,3) – a system of i linear equations containing i+1
unknowns (particular forces in the nodes and the total deflection) will be obtained in each node.
Themissing equation is obtained by equating the sum of force acting in particular nodes of the
contact line to the resultant force acting on the plate (4.5).



Load distribution in the worm meshing 1175

In the toothed gears it results from the action of the inter tooth force (Sabiniak, 1982, 1992;
Umezawa, 1974). The course of calculation procedure will be shown using an example.

6. A numerical example

Find the distribution of the inter tooth force between two cantilever plates:

• the circular (of steel) with material constants E1 = 2.06 · 10
11N/m2 and ν1 = 0.3 and

dimensions Rn1 =60mm – the external radius of the circular plate – of the worm convo-
lution apexes, R1 = 38mm – the internal radius of the circular plate – of the bases of
the worm convolution and h1 = 7.5mm – the thickness of the circular plate equal to the
average thickness of the worm teeth;

• in the shape of the circular sector (of bronze) with material constants E2 = 10
11N/m2

and ν2 = 0.35 and the dimensions R2 = 62mm – the external radius of the plate in the
shape of the circular sector – the radius of the bases of thewormwheel teeth,R2 =40mm
– the internal radius of the plate in the shape of the circular sector – the radius of apexes
of the teeth of the worm wheel and h2 =12mm – the thickness of the plate in the shape
of the circular sector equal to the average thickness of the worm wheel tooth contacting
each other along the line shown in Fig. 5 and designated as number I. The deflections of
the circular cantilever plate made of steel (the worm) in particular points of the contact
line amount to

ω150,−45 =
h21
πD1
(K
50,−45
50,−45F50,−45+K

50,−40
50,−45F50,−40+ . . .+K

50,40
50,−45F50,40+K

50,45
50,−45F50,45)

ω150,−40 =
h21
πD1
(K
50,−45
50,−40F50,−45+K

50,−40
50,−40F50,−40+ . . .+K

50,40
50,−40F50,40+K

50,45
50,−40F50,45)

...

ω150,40 =
h21
πD1
(K
50,−45
50,40 F50,−45+K

50,−40
50,40 F50,−40+ . . .+K

50,40
50,40F50,40+K

50,45
50,40F50,45)

ω150,45 =
h21
πD1
(K
50,−45
50,45 F50,−45+K

50,−40
50,45 F50,−40+ . . .+K

50,40
50,45F50,40+K

50,45
50,45F50,45)

(6.1)

Identical dependencesmust, of course, bewritten for the cantilever plate in the shape of the
circular sector made of bronze (the worm wheel). From the symmetry of the system occurring
for this case, it can be clearly seen that

F50,−45 =F50,45

F50,−40 =F50,40
...

F50,−5 =F50,5

F50,0 =F50,0

(6.2)

Expression (6.1) and the one obtained in the similar manner for the platemade of bronze, must
be substituted into condition (4.3), taking at the same time dependences (4.4) and (6.2) into
account. Then, while replacing the continuous load along the contact line with the concentrated
forces, 19 in number, andmaking transformations, a system of 10 linear homogeneous equations
will be obtained



1176 H.G. Sabiniak

Fig. 5. The net of division and the contact lines in the cylindrical wormmeshing

ω150,−45+ω
2
50,−45−ω=0

ω150,−40+ω
2
50,−40−ω=0

...

ω150,−5+ω
2
50,−5−ω=0

ω150,0+ω
2
50,0−ω=0

(6.3)

Substituting the values of Kri,ϕir,ϕ calculated in works (Sabiniak, 1982, 1986, 1992) and adding
condition (4.5), the following system of equations is obtained, allowing one to determine forces
in particular nodes of the net.

The calculation results are graphically presented in Fig. 6.

Fig. 6. The load distribution for contact line I according to Fig. 5

7. The mating of circular and rectangular cantilever plates

While searching for load distribution along the contact line in the globoidal meshing, the same
formulae (4.1)-(5.2) are applied.

Additional calculations are required only in the case of making linear equations for contact
line I (Fig. 7). Contact line I does not pass precisely through the net nodes. In this case,
interpolation is also used for finding the coefficients Kri,ϕir,ϕ , (Fig. 4). The procedure described
refers to the calculations carried out for both the polar and rectangular coordinates.

It has been decided that – for the rectangular plate – the nodes would occur where contact
line Iwould crosshorizontal lines of thenet.Following suchanassumption,with the interpolation



Load distribution in the worm meshing 1177

Fig. 7. The net of division and the contact lines in the globoidal wormmeshing

of the coefficient Kri,ϕir,ϕ for a plate in the shape of the circular sector, four adjacent points for
the net of polar coordinates are taken into consideration, as described in Section 4, and only
two adjacent points for the net of rectangular coordinates.

The shape and designations of the contact lines are shown in Fig. 7, while the load distri-
butions corresponding to particular contact lines in Figs. 8. The distributions of load obtained
for these lines do not differ radically, which results from a slight difference in the course of these
lines.

Fig. 8. The load distribution for contact line I according to Fig. 9

8. The results of theoretical and experimental investigations

Figure 9 presents the course of the contact lines on particular teeth of the worm wheel in the
worm gear studied, obtained during experimental investigations.

Figure 10 presents the stresses that occurred in the cylindrical worm meshing. The concen-
tration of stresses in particular points of contact for particular teeth is characteristic here.

Figure 11 is a diagram of changes in contact stresses along the contact line.

The contact line for tooth 6 (Fig. 9) can be equated to contact line I in Fig. 5. Here is a
slight divergence between the course of the contact line in the tooth contact area. Thus, the
stresses of Fig. 11 can be compared with the load distribution in Fig. 6. As there are principally
different quantities “stress” and “force” in these figures, there is no justification for comparing
them with respect to absolute values. However, as has been mentioned at the beginning of the
paper, experimental investigations aimed at the qualitative verification of the theory of load
distribution along the contact line (are not?) discussed in the present work.



1178 H.G. Sabiniak

Fig. 9. The real contact lines in the worm gear under investigation: (a) for the wormwheel tooth
entering the meshing, designated by number 5, (b) for the central wormwheel tooth being in the
meshing, designated by number 6, (c) for the wormwheel tooth leaving the meshing, designated

by number 7

Fig. 10. The state of stresses in the cylindrical wormmeshing in particular sections of the wormwheel
according to Fig. 9



Load distribution in the worm meshing 1179

Fig. 11. The changes in the contact stresses along the contact line in the cylindrical wormmeshing

In other words: if the load changes, its character along the contact line decreases, increases,
rapidly concentrates, fades, etc. The change in contact stresses should be of the same character
in the same places. The stresses in the tooth foot should assume a similar, although slightly
milder, character.When comparingFigs. 11 and 6with this respect, a similarity of the course of
load distribution and contact stresses along the contact lines discussed can be easily observed.

9. Directions of further investigations

The present work constitutes solely one of the problems which, as will be presented below, has
not been fully dealt with. It is one in thewhole range of problems related to globoidal meshings.

As has been mentioned in the works (Sabiniak, 1982, 1986, 1992; Hayman and Sabiniak,
1986; Predki, 1991), owing to its specificity, globoidal meshings possess a serious difficulty in
scientific studies, both theoretical and experimental. The skill of finding load distribution along
any contact line is a fundamental problem, the knowledge of which allows passing on to further
investigations in this field. The use of the knowledge and the load distribution along the contact
line is connected to finding an answer to the question: howwill themating surfaces of the teeth
be deformed under such a load? The problem of hertzian pressures along with the Bielajew
problem (Niemann and Winter, 1983) is currently relatively well-known and there seems to be
no difficulty in the adaptation of this knowledge to globoidal meshings.

The next step, which appears the obvious thing to do, is the introduction of an elastother-
mohydrodynamic oil film between themating teeth. Such attempts are already in progress.

If the oil film is to be considered, then the next step is the introduction of temperature into
the meshing and finding its distributions, both in the oil film and in particular mating teeth.
It is clear that a great amount of heat is released during the operation of worm gears. Thus,
the question arises what portion of the energy is changed into heat, and how it is dissipated.
There are works concerning basic studies on plates where the thermal problem has been solved.
However, temperature has been treated as a boundary condition there (Jaramillo, 1950; Timo-
shenko and Woinovsky-Krieger, 1959; Umezawa et al., 1969; Kączkowski, 1980). The solutions
in thermal investigations of plates thus presented are difficult to interpret physically and cannot
be practically applied in the problem discussed. The attempts at tackling the heat problem of
worm gears aim rather at operational uses than at elucidating the phenomena occurring in the
wormmeshing.

Thedevelopment of numericalmethods inmathematics, particularly of thefinite element and
finite difference methods (Sabiniak, 2012), allows finding load distributions in worm meshings
when the thickness of the tooth, as a plate, changes arbitrarily, which will probably be the next
stage in further research.

However, the problem of distribution of the load into particular pairs of mating teeth has
yet not been solved (Litwin, 1959; Niemann andWinter, 1983; Crosher, 2002; Dudás, 2005).

Either the problem of strain of the worm as a shaft has not been solved.



1180 H.G. Sabiniak

The deflections occurring in bearings and strains of the body should not be either forgotten
(Sabiniak andWoźniak, 1988).
All the above questions, as well as problems waiting to be solved, are static problems. One

can only realize the difficulties of the subject presented if motion is introduced.

10. Summary

Basing on the presented theoretical considerations and experimental investigations, as well as
on the results obtained, the following conclusions emerge:

1. The finite difference method used with regard to the search for deflections of cantilever
plates under arbitrary normal load offers in the solutions of these plates a very good
accuracy (Figs. 4-11). In particular, if boundary conditions are carefully selected, then the
divergence between the theoretical and experimental results are not greater than 14%.

2. The theoretical and experimental results obtained are in good agreement both for cylin-
drical and globoidal worm gears, which confirms the rightness of the presented theory of
searching for load distributions in the wormmeshing (Sabiniak, 2007).

3. The experimental method selected for the verification of the theory presented here should
be considered fully justified, although it has already been used for seeking the state of
stresses in the meshing. Its application for the presentation of the state of stresses in the
worm meshing only confirms the versatility of this method.

4. The results obtained indicate that the existing method of finding the radial course of the
contact lines in the tooth contact area (Niemann andWinter, 1983; Litwin, 1959; Crosher,
2002;Dudás, 2005)mustbeverified. It seems that themethodof obtaining the radial course
of the contact lines in the tooth contact area by using a great addendummodification in
the profile and circular profile of the meshing, at the cost of decreasing the tooth contact
area, and first of all, the length of the contact lines occurring simultaneously in the tooth
contact area, seems unjustified. A greater length of the contact line significantly reduces
the local stress of the materials and generally of the mating teeth thereby improving the
load-carrying capacity of the gear and its resistance to wear. Hence, the durability and
efficiency of the meshing will increase with length of the contact line in the tooth contact
area. It should be remembered, however, that the “straightening” of the contact lines in
the tooth contact area impairs, in turn, conditions for the formation of an oil film.

5. The above conclusions show that globoidal worm gears are superior to cylindrical worm
gears bothwith respect to their load-carrying capacity and life, which is nothing new.The
above results have again confirmed this truth. The problem that remains is the cost of
such a worm in relation to e.g. 1KW of the power transmitted. This is not so obvious.

6. A change in the character of the course of the contact line in the tooth contact area also
changes radically the character of the load distribution.

7. The results obtained are to be used for themodification of the profile of the teeth in order
to “equalize” the existing load distribution along the contact line.

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Load distribution in the worm meshing 1181

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Manuscript received May 14, 2015; accepted for print February 12, 2016