LIMITERS PREVENT OVERLOADING
These 13 “safety valves” give way if machinery jams,
thus preventing serious damage.
343
Fig. 6 The ring resists the natural ten-
dency of the rollers to jump out of the
grooves in the reduced end of one shaft.
The slotted end of the hollow shaft acts as
a cage.
Fig. 7 Sliding wedges clamp down on
the flattened end of the shaft. They spread
apart when torque becomes excessive. The
strength of the springs in tension that hold
the wedges together sets the torque limit.
Fig. 8 Friction disks are compressed by
an adjustable spring. Square disks lock into
the square hole in the left shaft, and round
disks lock onto the square rod on the right
shaft.
Fig. 1 A shear pin is a simple and reliable
torque limiter. However, after an overload,
removing the sheared pin stubs and replac-
ing them with a new pin can be time con-
suming. Be sure that spare shear pins are
available in a convenient location.
Fig. 2 Friction clutch torque limiter. Adjustable spring
tension holds the two friction surfaces together to set the
overload limit. As soon as an overload is removed, the
clutch reengages. A drawback to this design is that a slip-
ping clutch can destroy itself if it goes undetected.
Sclater Chapter 10 5/3/01 1:07 PM Page 343
344
Fig. 3 Mechanical keys. A spring holds a ball in a dim-
ple in the opposite face of this torque limiter until an over-
load forces it out. Once a slip begins, clutch face wear
can be rapid. Thus, this limiter is not recommended for
machines where overload is common.
Fig. 4 A cylinder cut at an angle forms a torque limiter. A spring clamps the
opposing-angled cylinder faces together, and they separate from angular align-
ment under overload conditions. The spring tension sets the load limit.
Fig. 5 A retracting key limits the torque in this clutch. The ramped sides
of the keyway force the key outward against an adjustable spring. As the
key moves outward, a rubber pad or another spring forces the key into a
slot in the sheave. This holds the key out of engagement and prevents
wear. To reset the mechanism, the key is pushed out of the slot with a tool
in the reset hole of the sheave.
Fig. 6 Disengaging gears. The axial forces of a
spring and driving arm are in balance in this torque
limiter. An overload condition overcomes the force of
the spring to slide the gears out of engagement.
After the overload condition is removed, the gears
must be held apart to prevent them from being
stripped. With the driver off, the gears can safely be
reset.
Fig. 7 A cammed sleeve connects the input and output shafts of this
torque limiter. A driven pin pushes the sleeve to the right against the
spring. When an overload occurs, the driving pin drops into the slot to
keep the shaft disengaged. The limiter is reset by turning the output shaft
backwards.
Sclater Chapter 10 5/3/01 1:07 PM Page 344
345
Fig. 8 A magnetic fluid is the coupler in this
torque limiter. The case is filled with a mixture
of iron or nickel powder in oil. The magnetic
flux passed through the mixture can be con-
trolled to vary the viscosity of the slurry. The
ability to change viscosity permits the load limit
to be varied over a wide range. Slip rings carry
electric current to the vanes to create the mag-
netic field.
Fig. 9 A fluid is the coupling in this torque
limiter. Internal vanes circulate the fluid in
the case. The viscosity and level of the fluid
can be varied for close control of the maxi-
mum load. The advantages of this coupling
include smooth torque transmission and low
heat rise during slip.
Fig. 10 The shearing of a pin releases
tension in this coupling. A toggle-operated
blade shears a soft pin so that the jaws
open and release an excessive load. In an
alternative design, a spring that keeps the
jaws from spreading replaces the shear pin.
Fig. 11 A spring plunger provides reciprocating motion
in this coupling. Overload can occur only when the rod is
moving to the left. The spring is compressed under an
overload condition.
Fig. 12 Steel shot transmits more torque
in this coupling as input shaft speed is
increased. Centrifugal force compresses
the steel shot against the outer surfaces of
the case, increasing the coupling’s resist-
ance to slip. The addition of more steel shot
also increases the coupling’s resistance to
slip.
Fig. 13 A piezoelectric crystal pro-
duces an electric signal that varies with
pressure in this metal-forming press.
When the amplified output of the
piezoelectric crystal reaches a present
value corresponding to the pressure
limit, the electric clutch disengages. A
yielding ring controls the compression
of the piezoelectric crystal.
Sclater Chapter 10 5/3/01 1:07 PM Page 345
346
SEVEN WAYS TO LIMIT SHAFT ROTATION
Traveling nuts, clutch plates, gear fingers, and pinned members
form the basis of these ingenious mechanisms.
Mechanical stops are often required in automatic machinery and servomechanisms to
limit shaft rotation to a given number of turns. Protection must be provided against
excessive forces caused by abrupt stops and large torque requirements when machine
rotation is reversed after being stopped.
Fig. 1 A traveling nut moves along the threaded shaft until the
frame prevents further rotation. This is a simple device, but the travel-
ing nut can jam so tightly that a large torque is required to move the
shaft from its stopped position. This fault is overcome at the expense
of increased device length by providing a stop pin in the traveling nut.
Fig. 2 The engagement between the pin and the rotating finger
must be shorter than the thread pitch so the pin can clear the finger
on the first reverse-turn. The rubber ring and grommet lessen the
impact and provide a sliding surface. The grommet can be oil-
impregnated metal.
Fig. 3 Clutch plates tighten and stop their rotation
as the rotating shaft moves the nut against the
washer. When rotation is reversed, the clutch plates
can turn with the shaft from A to B. During this
movement, comparatively low torque is required to
free the nut from the clutch plates. Thereafter, sub-
sequent movement is free of clutch friction until the
action is repeated at the other end of the shaft. The
device is recommended for large torques because
the clutch plates absorb energy well.
Sclater Chapter 10 5/3/01 1:07 PM Page 346
347
Fig. 4 A shaft finger on the output shaft hits the
resilient stop after making less than one revolu-
tion. The force on the stop depends upon the gear
ratio. The device is, therefore, limited to low ratios
and few turns, unless a worm-gear setup is used.
Fig. 5 Two fingers butt together at the initial and final positions to prevent rotation
beyond these limits. A rubber shock-mount absorbs the impact load. A gear ratio of
almost 1:1 ensures that the fingers will be out-of-phase with one another until they
meet on the final turn. Example: Gears with 30 to 32 teeth limit shaft rotation to 25
turns. Space is saved here, but these gears are expensive.
Fig. 6 A large gear ratio limits the idler gear to less than one turn.
Stop fingers can be added to the existing gears in a train, making this
design the simplest of all. The input gear, however, is limited to maxi-
mum of about five turns.
Fig. 7 Pinned fingers limit shaft turns to approximately N + 1 revo-
lutions in either direction. Resilient pin-bushings would help reduce
the impact force.
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348
MECHANICAL SYSTEMS FOR CONTROLLING
TENSION AND SPEED
The key to the successful operation of any continuous-processing
system that is linked together by the material being processed is
positive speed synchronization of the individual driving mecha-
nisms. Typical examples of such a system are steel mill strip
lines, textile processing equipment, paper machines, rubber and
plastic processers, and printing presses. In each of these examples,
the material will become wrinkled, marred, stretched or otherwise
damaged if precise control is not maintained.
FIG. 1—PRIMARY INDICATORS
FIG. 2—SECONDARY INDICATORS
FIG. 3—CONTROLLERS AND ACTUATORS
Sclater Chapter 10 5/3/01 1:07 PM Page 348
The automatic control for such a sys-
tem contains three basic elements: The
signal device or indicator, which senses
the error to be corrected; the
controller,
which interprets the indicator signal and
amplifies it, if necessary, to initiate con-
trol action; and the
transmission, which
operates from the controller to change
the speed of the driving mechanism to
correct the error.
Signal indicators for continuous sys-
tems are divided in two general classifi-
cations:
Primary indicators that measure
the change in speed or tension of the
material by direct contact with the mate-
rial; and
secondary indicators that meas-
ure a change in the material from some
reaction in the system that is proportional
to the change.
The primary type is inherently more
accurate because of its direct contact
with the material. These indicators take
the form of contact rolls, floating or com-
pensating rolls, resistance bridges and
flying calipers, as illustrated in Fig. 1. In
each case, any change in the tension,
velocity, or pressure of the material is
indicated directly and immediately by a
displacement or change in position of the
indicator element. The primary indicator,
therefore, shows deviation from an estab-
lished norm, regardless of the factors that
have caused the change.
Secondary indicators, shown in Fig.
2, are used in systems where the material
cannot be in direct contact with the indi-
cator or when the space limitations of a
particular application make their use
undesirable. This type of indicator intro-
duces a basic inaccuracy into the control
system which is the result of measuring
an error in the material from a reaction
that is not exactly proportional to the
error. The control follows the summation
of the errors in the material and the indi-
cator itself.
The controlling devices, which are
operated by the indicators, determine the
degree of speed change required to cor-
rect the error, the rate at which the cor-
rection must be made, and the stopping
point of the control action after the error
has been corrected. The manner in which
the corrective action of the controller is
stopped determines both the accuracy of
the control system and the kind of con-
trol equipment required.
Three general types of control action
are illustrated in Fig. 3. Their selection
for any individual application is based on
the degree of control action required, the
amount of power available for initiating
the control, that is, the torque amplifica-
tion required, and the space limitations of
the equipment.
The on-and-off control with timing
action is the simplest of the three types. It
functions in this way: when the indicator
is displaced, the timer contact energizes
the control in the proper direction for
correcting the error. The control action
continues until the timer stops the action.
After a short interval, the timer again
energizes the control system and, if the
error still exists, control action is contin-
ued in the same direction. Thus, the con-
trol process is a step-by-step response to
make the correction and to stop the oper-
ation of the controller.
The proportioning controller corrects
an error in the system, as shown by the
indicator, by continuously adjusting the
actuator to a speed that is in exact pro-
portion to the displacement of the indica-
tor. The diagram in Fig. 3 shows the pro-
portioning controller in its simplest form
as a direct link connection between the
indicator and the actuating drive.
However, the force amplification
between the indicator and the drive is rel-
349
Sclater Chapter 10 5/3/01 1:07 PM Page 349
atively low; thus it limits this controller
to applications where the indicator has
sufficient operating force to adjust the
speed of the variable-speed transmission
directly.
The most accurate controller is the
proportioning type with throttling action.
Here, operation is in response to the rate
or error indication. This controller, as
shown in Fig. 3, is connected to a throt-
tling valve, which operates a hydraulic
servomechanism for adjusting the vari-
able-speed transmission.
The throttling action of the valve pro-
vides a slow control action for small
error correction or for continuous correc-
tion at a slow rate. For following large
error, as shown by the indicator, the
valve opens to the full position and
makes the correction as rapidly as the
variable-speed transmission will allow.
Many continuous processing systems
can be automatically controlled with a
packaged unit consisting of a simple,
mechanical, variable-speed transmission
and an accurate hydraulic controller.
This controller-transmission package
can change the speed relationship at the
driving points in the continuous system
from any indicator that signals for cor-
rection by a displacement. It has anti-
hunting characteristics because of the
throttling action on the control valve, and
is self-neutralizing because the control
valve is part of the transmission adjust-
ment system.
The rotary printing press is an exam-
ple of a continuous processing system
that requires automatic control. When
making billing forms on a press, the
printing plates are rubber, and the forms
are printed on a continuous web or paper.
The paper varies in texture, moisture
content, flatness, elasticity, and finish. In
addition, the length of the paper changes
as the ink is applied.
In a typical application of this kind,
the accuracy required for proper registry
of the printing and hole punching must
be held to a differential of
1
⁄32 in. in 15 ft
of web. For this degree of accuracy, a
floating or compensating roll, as shown
in Fig. 4, serves as the indicator because
it is the most accurate way to indicate
changes in the length of the web by dis-
placement. In this case, two floating rolls
are combined with two separate con-
trollers and actuators. The first controls
the in-feed speed and tension of the
paper stock, and the second controls the
wind-up.
The in-feed is controlled by maintain-
ing the turning speed of a set of feeding
rolls that pull the paper off the stock roll.
The second floating roll controls the
speed of the wind-up mandrel. The web
of paper is held to an exact value of ten-
sion between the feed rolls and the
punching cylinder of the press by the in-
feed control. It is also held between the
punching cylinder and the wind-up roll.
Hence, it is possible to control the ten-
sion in the web of different grades of
paper and also adjust the relative length
at these two points, thereby maintaining
proper registry.
The secondary function of maintain-
ing exact control of the tension in the
paper as it is rewound after printing is to
condition the paper and obtain a uni-
formly wound roll. This makes the web
ready for subsequent operations.
The control of dimension or weight
by tension and velocity regulation can be
illustrated by applying the same general
type of controller actuator to the take-
odd conveyors in a extruder line such as
those used in rubber and plastics process-
ing. Two problems must be solved: First,
to set the speed of the take-away con-
veyor at the extruder to match the varia-
tion in extrusion rate; and, second, to set
the speeds of the subsequent conveyor
sections to match the movement of the
stock as it cools and tends to change
dimension.
One way to solve these problems is to
use the pivoted idlers or contact rolls as
indicators, as shown in Fig. 5. The rolls
contact the extruded material between
each of the conveyor sections and control
the speed of the driving mechanism of
the following section. The material forms
a slight catenary between the stations,
and the change in the catenary length
indicates errors in driving speeds.
The plasticity of the material prevents
the use of a complete control loop. Thus,
the contract roll must operate with very
little resistance or force through a small
operating angle.
The difficulties in winding or coiling
a strip of thin steel that has been plated or
pre-coated for painting on a continuous
basis is typical of processing systems
whose primary indicators cannot be used.
While it is important that no contact be
made with the prepared surface of the
steel, it also desirable to rewind the strip
after preparation in a coil that is sound
and slip-free. An automatic, constant-
350
Speed and Tension Control (continued )
Fig 4 Floating rolls are direct indicators of speed and tension in the paper web. Controller-
actuators adjust feed and windup rolls to maintain registry during printing.
Fig. 5 Dimension control of extruded materials calls for primary indicators like the contact
rolls shown. Their movements actuate conveyor control mechanisms.
Sclater Chapter 10 5/3/01 1:07 PM Page 350
tension winding control and a secondary
indicator initiate the control action.
The control system shown in Fig. 6 is
used in winding coils from 16 in. core
diameter to 48 in. maximum diameter.
The power to wind the coil is the con-
trolling medium because, by maintain-
ing constant winding power as the coil
builds up, a constant value of strip ten-
sion can be held within the limits
required. Actually, this method is so
inaccurate that the losses in the driving
equipment (which are a factor in the
power being measured) are not constant;
hence the strip tension changes slightly.
This same factor enters into any control
system that uses winding power as an
index of control.
A torque-measuring belt that operates
a differential controller measures the
power of the winder. Then, in turn, the
controller adjusts the variable-speed
transmission. The change in speed
between the source of power and the
transmission is measured by the three-
shaft gear differential, which is driven in
tandem with the control belt. Any change
in load across the control belt produces a
change in speed between the driving and
driven ends of the belt. The differential
acts as the controller, because any change
in speed between the two outside shafts
of the differential results in a rotation or
displacement of the center or control
shaft. By connecting the control shaft of
the differential directly to a screw-
controlled variable-speed transmission, it
is possible to adjust the transmission to
correct any change in speed and power
delivered by the belt.
This system is made completely auto-
matic by establishing a neutralizing
speed between the two input shaft of the
differential (within the creep value of the
belt). When there is no tension in the
strip (e.g., when it is cut), the input speed
to the actuator side of the differential is
higher on the driven side than it is on the
driving side of the differential. This
unbalance reverses the rotation of the
control shaft of the differential, which in
turn resets the transmission to high speed
required for starting the next coil on the
rewinding mandrel.
In operation, any element in the sys-
tem that tends to change strip tension
causes a change in winding power. This
change, in turn, is immediately compen-
sated by the rotation (or tendency to
rotate) of the controlling shaft in the dif-
ferential. Hence, the winding mandrel
speed is continuously and automatically
corrected to maintain constant tension in
the strip.
When the correct speed relationships
are established in the controller, the sys-
tem operates automatically for all condi-
tions of operation. In addition, tension in
the strip can be adjusted to any value by
moving the tension idler on the control
belt to increase or decrease the load
capacity of the belt to match a desired
strip tension.
There are many continuous process-
ing systems that require constant velocity
of the material during processing, yet do
not require accurate control of the ten-
sion in the material. An example of this
process is the annealing of wire that is
pulled off stock reels through an anneal-
ing furnace and then rewound on a wind-
up block.
The wire must be passed through the
furnace at a constant rate so that the
annealing time is maintained at a fixed
value. Because the wire is pulled through
the furnace by the wind-up blocks,
shown in Fig. 7, its rate of movement
through the furnace would increase as
the wire builds up on the reels unless a
control slows down the reels.
A constant-velocity control that
makes use of the wire as a direct indica-
tor measures the speed of the wire to ini-
tiate a control action for adjusting the
speed of the wind-up reel. In this case,
the wire can be contacted directly, and a
primary indicator in the form of a contact
roll can register any change in speed. The
contact roll drives one input shaft of the
differential controller. The second input
shaft is connected to the driving shaft of
the variable-speed transmission to pro-
vide a reference speed. The third, or con-
trol, shaft will then rotate when any dif-
ference in speed exists between the two
input shafts. Thus, if the control shaft is
connected to a screw-regulated actuator,
an adjustment is obtained for slowing
down the wind-up blocks as the coils
build up and the wire progresses through
the furnace at a constant speed.
351
Fig. 6 The differential controller has a third shaft that signals the remote actuator when ten-
sion in sheet material changes. Coiler power is a secondary-control index.
Fig. 7 The movement of wire through the annealing furnace is regulated at constant velocity
by continuously retarding the speed of the windup reels to allow for wire build-up.
Sclater Chapter 10 5/3/01 1:07 PM Page 351
352
DRIVES FOR CONTROLLING TENSION
Mechanical, electrical, and hydraulic methods for obtaining
controlled tension on winding reels and similar drives, or for
driving independent parts of a machine in synchronism.
the difference between the coefficient of
friction at the start and the coefficient of
sliding friction. Sliding friction will be
affected by moisture, foreign matter, and
wear of the surfaces.
Capacity is limited by the heat radiat-
ing capacity of the brake at the maximum
permissible running temperature.
Differential drives can take many dif-
ferent forms, e.g., epicycle spur gears,
bevel gear differentials, or worm gear
differentials.
The braking device on the ring gear or
spider could be a band brake, a fan, an
impeller, an electric generator, or an elec-
tric drag element such as a copper disk
rotating in a powerful magnetic field. A
brake will give a drag or tension that is
MECHANICAL DRIVES
reasonably constant over a wide speed
range. The other braking devices men-
tioned here will exert a torque that will
vary widely with speed, but will be defi-
nite for any given speed of the ring gear
or spider.
A definite advantage of any differen-
tial drive is that maximum driving torque
can never exceed the torque developed
by the braking device.
Differential gearing can be used to
control a variable-speed transmission. If
the ring gear and sun gear are to be
driven in opposite directions from their
respective shafts which are to be held in
synchronism, the gear train can be
designed so that the spider on which the
planetary gears are mounted will not
rotate when the shafts are running at the
desired relative speeds. If one or the
other of the shafts speeds ahead, the spi-
der rotates correspondingly. The spider
rotation changes the ratio of the variable-
speed transmission unit.
ELECTRICAL DRIVES
The shunt-field rheostat in a DC
motor drive can be used to synchronize
drives. When connected to a machine for
processing paper, cloth, or other sheet
material that is passing around a take-up
roll, the movement of the take-up roll
moves a control arm which is connected
to the rheostat. This kind of drive is not
suitable for wide changes of speed that
exceed about a 2.5 to 1 ratio.
For wide ranges of speed, the rheostat
is put in the shunt field of a DC generator
that is driven by another motor. The volt-
age developed by the generator is con-
trolled from zero to full voltage. The
generator furnishes the current to the
driving motor armature, and the fields of
the driving motor are separately excited.
Thus, the motor speed is controlled from
zero to maximum.
A band brake is used on coil winders,
insulation winders, and similar machines
where maintaining the tension within
close limits is not required.
It is simple and economical, but ten-
sion will vary considerably. Friction drag
at start-up might be several times that
which occurs during running because of
Sclater Chapter 10 5/3/01 1:08 PM Page 352
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