more particularlyto rotary dryers a

more particularly
to rotary dryers adapted for use in the drying of heavy
wet materials which are difficult to handle by ordinary
drying methods. The drying of marl, wet ores, and
‘similar wet, heavy and sticky materials has been a diffi
cult problem in the past and the dryers which have
been heretofore proposed have not been entirely satis
factory for the drying of such materials. Various types
of dryers are known in the art and various types of rotary
dryers in particular have been built and used for a variety
of purposes. None of these dryers is, however, able to
handle sticky, heavy wet materials in a single pass and
with any degree of rapidity.
The present invention provides a dryer of the rotary
type which is able to satisfactorily handle the heaviest
wet and sticky materials presently known in commercial
practices with speed and thoroughness. I provide a dryer
preferably comprising an outer cylindrical shell, drive means operatively connected to said shell whereby the
shell is rotated, a plurality of inner duct members of
successively smaller cross section forming. an axially ex
tending duct within the shell, an opening into the in
terior of the shell at the end of each duct member, means connected to one end of said axially extending duct de
livering heated air thereto, means on the interior of the
shell raising material therein to deposit it on the duct
members and means on the periphery of each duct mem
ber extending outwardly therefrom to a line equidistant
from the said means on the drum interior for raising ma
terial. Preferably the drive means is a plurality of cable
windings about a sheave on the outer periphery of the
shell and a driven ‘sheave spaced therefrom. This drive
permits ready change in the speed of rotation as well as changes in the slope of the outer shell. Preferably the
inner duct members are overlapped or telescoped at their
ends to form a restricted passage between the inner and
outer duct member. Preferably the shelf forming means
on each duct is connected with the duct and extends
outwardly therefrom to a line substantially parallel to
the periphery of the shell, thus providing increasingly
larger shelf areas as the ducts decrease in size. Pref
erably each shell is provided with a support brace at each
end having a ?ange normal to the surface of the shelf,
thereby providing closed ends and- permitting material to
be dried to lie on the shelves in considerable depth.
The foregoing statement has set out certain objects,
purposes and advantages of the present invention. Other
objects, purposes and advantages will be apparent from a consideration of the following description and the ac
companying drawings in which:
Figure 1 is a side elevational view of a rotary dryer
according to my invention.
Figure 2 is a longitudinal section through the dryer
shell of the dryer of Figure 1 showing the inner duct in
elevation.
Figure 3 is an end elevational view of the dryer of
Figure 1 viewed at the entry end of the dryer shell.
Figure 4 is a section on the line IV-IV of Figure 2.
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2,818,657
Fatented Jan. 7, 1958
2
Figures 5, 6 and 7 are schematic and elevational views
of three different forms of inner duct which may be
used. in the dryer of this invention.
Figure 8 is a fragmentary isometric view of a brace
member used in this invention.
Referring to the drawings, I have illustrated a cylin
drical dryer shell 10 provided with tires 11 supported
for rotation on rollers 12 rotatably mounted in a base
13. A peripheral sheave 14 is ?tted on the exterior of
the shell 10. A drive sheave 15 is spaced from and in
line with the sheave 14 and is connected through a speed
reducer 16 to a drive motor 17. A plurality of cables
(not shown) pass around the sheaves 14 and Hand act
to drive the shell 10 for rotation. The cable drive per
mits easy, rapid changes in vspeed of rotation as well as changes in the slope of the dryer itself. This case of
change permits considerable variation in speed of feed
through as well as in time of contact with the drying areas
of the dryer. Guide wheels 18 rotatably mounted on the
base 13 contact the opposite edges of the tire 11 and
maintain the shell 10 in alignment on the rollers 12.
A loading chute 19 is provided at the entry end of the
shell 10.
Lifting ?ights 20 are provided on the interior of the
shell 10. These lifting ?ights ‘are preferably placed at an angle to the radius of the shell to carry material in
the shell upwardly along the path of rotation and then
discharge the material through the center of the shell.
A heating duct generally indicated by the numeral 21
extends axially through the shell 10, terminating short
of the end of the shell to provide an accumulating and
discharge portion 22. The duct 21 is made up of a plu
rality of ?ve sided hollow members 21a, 21b, 21c and. 21d
of successively smaller sizes. The ends of each succes sively smaller hollow member is preferably telescoped
within the end of the adjacent larger member for a
short distance to providev a passageway 23 therebetween
through which hot drying gas is introduced into the
interior of the shell 10 at spaced points intermediate its
length. Each duct member 21a, 21b, 21c and 21d is
provided at each end with a plurality of brace members
24, preferably made up of spaced angles 24a and 2%
connected by a plate 24c forming an elongated pocket.
Plates 25 are welded to each pair of braces and to
the member to form shelves, which may be in effect con
tinuations of the sides of the hollow members. Each
such shelf forms with the angle of the brace member 24
and the rear of the preceding shelf, a pocket or trough
which catches material falling from the lifting ?ights 20
and maintains it in contact with the hot duct surfaces
as the dryer rotates until the rotation inverts the ‘shelves
and discharges the material to the shell wall. Hot, drying
gases are introduced into the interior of the duct 21 from
a furnace 26 which is of conventional design.
The operation of the dryer of this invention is as fol
lows. The material to be dried is fed into the loading
chute 19 from which it passes directly into the interior
of the shell 10. The lifting ?ights 20 pick up the ma
terial to be dried and carry it upwardly about the- cir
curnference of rotation. As the material approaches the
top of the circle of rotation it begins to cascade down
wardly through the hot interior of the dryer. A large
percentage of the cascading material is caught in the
pockets or troughs formed by the ducts 21a, 21b, 21c
and 21d and the shelves or plates 25 where the material
is subject to the heat transmitted from the duct before
dropping again to the lower part of the dryer. This
cycle is repeated through the length of the heating duct
until the material reaches the discharge portion 22. In
the discharge portion 22 the material is rolled onwardly
to ?nal discharge.
The hot air or gases entering the duct 21 passes through 2,818,657
3
section 21a. A portion of the hot gases is permitted to
enter into the interior of the shell 10 through the passage
23. The balance of the gases there passes through the
next duct section 21b at the end of which another por
tion of the hot gases is permitted to enter into the interior
of the shell 10 through passageway 23. This is repeated
to the end of the duct 21. The introduction of hot air or
gases into the shell maintains the vapors in the interior
of the shell above the dew point and thereby prevents
already dry material from absorbing moisture and aids
in the removal of moisture from the cascading material
which has not yet been dried.
A damper 21]‘ may be installed at the end of the last
duct member 21d to restrict the out?ow of hot gases from
the ducts and to vary the flow through the passageways
23 by building up the pressure in the duct.
The duct members 21a, 21b, 21c and 21d may take
other forms than that of the ?ve sided duct shown in
Figures 1 through 4. The duct member may be in the
form of a cylinder 30 with plates 31 extending tangential
ly outwardly from the periphery (see Figure 5). Alter
natively the duct member 32 may be square in cross
section with plates 33 forming extensions of the sides
(see Figure 6) or the duct member 34 may be triangular
in section with plates 35 forming extensions of the sides
(see Figure 7).
The dryer of the present invention, because of its novel
construction, subjects the material to be dried to a more
thorough drying action, maintains the material in contact
with the hot zone longer and more effectively prevents
formation of condensate in the interior of the dryer than
any of the dryers now known.
which were di?icult or impossible to handle in ordinary
rotary dryers can be handled with ease in the present dryer.
While I have illustrated and described certain pre
ferred embodiments of my invention, it will be understood
that it may be otherwise embodied within the scope of
the following claims.
I claim:
1. A rotary dryer comprising an outer cylindrical shell,
drive means operatively connected to said shell whereby
said shell is rotated, a plurality of inner duct members,
each of successively smaller cross section forming an
axially extending duct within and connected to said shell, an opening into the interior of the shell at the end of
each such duct member, means connected to said duct
members supplying heated air thereto and means on the
periphery of each duct member extending outwardly from
the periphery thereof to a line spaced from the interior of
the shell and forming an axially extending trough with the
duct wall, all of said means being substantially equally
spaced from the interior of the shell.
2. A rotary dryer comprising an outer cylindrical shell,
drive means operatively connected to said shell whereby
said shell is rotated, a plurality of inner duct members,
each of successively smaller cross section forming an
axially extending duct within said sheil, an opening into
the interior of the shell at the end of ea