Spring applied, electric released drum brake

A spring-applied, electrically released drum brake which is self-energizing in one direction, and partially deenergizing in the other direction. Regardless of braking direction, the brake shoes are applied with substantially zero force, with the braking force being increased to decelerate and stop the drum within predetermined jerk and deceleration constraints.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The invention relates in general to drum brakes, and more specifically to 
spring-applied, electrically released drum brakes. 
2. Description of the Prior Art 
Escalators are provided with an electrically released, mechanically applied 
brake capable of stopping an up or down traveling escalator with any load 
up to brake design load. 
The maximum braking effort is required to stop a fully loaded escalator 
going down, and thus the brake is sized accordingly. For example, the 
brake torque is selected to provide some minimum value of deceleration, 
such as about 1 ft/sec.sup.2, when an escalator with rated load is stopped 
while transporting passengers from an upper landing to a lower landing. 
Thus, any other condition than a fully loaded escalator going down will 
result in a higher rate of deceleration. The highest rate of deceleration 
would occur when a fully loaded escalator is braked to a stop while 
transporting passengers from the lower landing to the upper landing. This 
may be about 8 to 10 ft/sec.sup.2 for a typical escalator with a fixed 
braking torque. 
The prior art has disclosed many different arrangements which adjust the 
braking effort, in order to decrease the range between the minimum and 
maximum rates of deceleration which may occur, by taking such things as 
speed, load, and/or travel direction into account. For example, the 
braking effort may be adjusted according to load, according to speed, such 
as in response to an error signal which is responsive to the difference 
between the actual speed and the desired speed of the escalator while 
braking to a stop, or in response to travel direction. In general, such 
controlled braking arrangements add substantially to the cost of an 
escalator, as well as to the maintenance thereof, because of the more 
complex mechanical and/or electrical apparatus required. 
It would be desirable to provide a new and improved brake suitable for an 
escalator which will inherently provide substantially less braking force 
in one direction than the other, enabling such a brake to be used to 
inherently brake with a greater force when the escalator is moving such 
that it would transport passengers from an upper to a lower landing. 
It would further be desirable to provide a new and improved brake with the 
above-mentioned inherent directional braking effort capabilities, which 
will apply the braking force within predetermined jerk and deceleration 
constraints, with a deceleration rate which is substantially constant, 
regardless of load, for a down traveling escalator. 
SUMMARY OF THE INVENTION 
Briefly, the present invention is a new and improved fail-safe brake which 
inherently applies a greater braking effort in one direction of rotation 
than in the other direction, and which applies a braking torque to the 
object to be braked which starts at substantially zero braking force and 
increases at a controlled rate. Thus, this new and improved brake is 
ideally suited for an escalator. 
More specifically, the new and improved brake is a spring-applied, 
electrically released drum brake having brake shoes mounted such that they 
are of the leading type in one direction of drum rotation, wherein shoe 
actuation in this direction of drum rotation assists the actuating force. 
This assist is called "self-energization." In the other direction of 
rotation, the shoes are of the trailing type, wherein shoe actuation 
opposes the actuating force. 
Further, instead of applying a fixed braking torque upon brake actuation, 
the brake is arranged to cause the brake shoes to contact the brake drum 
with very little initial braking force, and to build the braking force to 
provide a predetermined deceleration rate which increases to a 
predetermined maximum deceleration rate with a controlled slope which 
maintains jerk below a very low magnitude, such as 6 ft/sec.sup.3.

DESCRIPTION OF PREFERRED EMBODIMENTS 
Referring now to the drawings, and to FIG. 1 in particular, there is shown 
an escalator of the type which may utilize the teachings of the invention. 
Escalator 10 employs a conveyor 12 for transporting passengers between a 
first or lower landing 14 and a second or upper landing 16. The conveyor 
12 is of the endless type, having an upper load bearing run 18 on which 
passengers stand while being transported between the landings, and a lower 
return run 20. 
A balustrade 22 is disposed above the conveyor 12 for guiding a continuous, 
flexible handrail 24. 
Conveyor 12 includes a plurality of steps 36, only a few of which are shown 
in FIG. 1. The steps are each clamped to a step axle, and they move in a 
closed path, with the conveyor 12 being driven by the modular drive 
arrangement disclosed in U.S. Pat. No. 3,677,388, which is assigned to the 
same assignee as the present application. 
As disclosed in U.S. Pat. No. 3,677,388, the conveyor 12 includes an 
endless belt 30 having first and second sides, with each side being formed 
of toothed links 38, interconnected by the step axles to which the steps 
36 are connected. The steps 36 are supported by main and trailer rollers 
40 and 42, respectively, at opposite sides of the endless belt 30. The 
main and trailer rollers 40 and 42 cooperate with support and guide tracks 
46 and 48, respectively, to guide the steps 3 in the endless path or loop. 
The steps 36 are driven by a modular drive unit 52 which includes sprocket 
wheels, and a drive chain for engaging the tooth links 38. The modular 
drive unit 52 includes a handrail drive pulley 54 on each side of the 
conveyor which drives a handrail unit 56. 
FIG. 2 is a plan view of drive unit 52 shown in FIG. 1. In general, drive 
unit 52 includes a drive motor 60, such as a three-phase 60 Hz. induction 
motor, a gear reducer 62, drive sprocket wheels 64 and 66, and idler 
sprocket wheels 68 and 70. The gear reducer 62, which may be a commercial 
36.2:1 gear reducer, has an input shaft 72 and an output shaft 74. The 
drive motor 60 has a motor shaft 76. The motor shaft 76 is coupled to the 
input shaft 72 of the gear reducer 62 by any suitable means, such as via 
pulleys 78 and 80, and a timing belt 82. A broken belt switch 84 monitors 
the integrity of belt 82. 
The output shaft 74 of gear reducer 62 is connected to the drive sprockets 
64 and 66, and each driven sprocket is coupled with an idler sprocket via 
a drive chain 86. As illustrated, the drive chain may have three strands, 
with the outer two strands engaging teeth on the sprocket, and with the 
inner strand engaging the teeth on the toothed links 38, to drive the 
endless belt 30 about its guided loop. A fail-safe friction brake 90, 
which is electrically released and mechanically applied, is mounted on 
input shaft 72 of the gear reducer 62. Brake 90 is constructed according 
to the teachings of the invention. 
FIG. 3 is an elevational view of brake 90, with certain parts cut away in 
order to more clearly illustrate the operational details of the brake. 
Brake 90 includes a mounting plate 92 having a slot 94 for receiving the 
input shaft 72 of the speed reducer 62 shown in FIG. 2. Brake 90 includes 
a rotatable first brake element or brake drum 96, which includes a 
circular flat wall portion 98 which extends from a central opening 100 to 
an outer cylindrical flange 102. The majority of the wall portion 98 is 
illustrated being cut away in FIG. 2, in order to reveal the brake 
operating mechanism which is normally concealed within the drum 96. Flange 
102 includes an inner surface 104, which forms one of the friction 
surfaces of the brake 90, and an outer surface 106. As illustrated, 
uniformly spaced teeth 108 may be formed about the outer circumference of 
the flange 102, such as adjacent to the perimetrical edge of the flange. 
The purpose of such teeth will be hereinafter explained. Brake drum 96 is 
mounted on reducer shaft 72 via a bushing 110. Opening 100 in drum 96 may 
be formed by a mounting hub having a tapered opening, and bushing 110 may 
have a cylindrical portion having an I.D. sized to fit the O.D. of shaft 
72, and an O.D. tapered to complement the tapered opening in the drum. A 
flange 112 on bushing 110 has openings for receiving mounting bolts 114, 
which threadably engage tapped openings in the drum. 
A second braking element comprising brake shoes are disclosed to co-act 
with the drum 96, such as first and second brake shoes 116 and 118. Brake 
shoe 116 has one end pivotally fixed to plate 92 via pivot pin 120, and 
brake shoe 118 has one end pivotally fixed to mounting plate 92 via pivot 
pin 122. Brake pads 124 and 126 on brake shoes 116 and 118, respectively, 
contact surface 104 of brake drum 96 when brake 90 is applied. Brake pads 
124 and 126 are designed to have a slightly smaller radius than the radius 
of inner surface 104. This arrangement controls initial and subsequent 
contact with the drum, wherein the pads 124 and 126 are caused to contact 
surface 104 of drum 96 with their intermediate portions, leaving small 
clearances between the pads and the drum at both ends of the pad, such as 
clearance 128 between one end of pad 124 and surface 104. This arrangement 
aids the seating-in of the brake pads, and provides better control over a 
self-energizing feature of the brake in one rotational direction of the 
drum 96, as will be hereinafter explained. 
A brake actuating lever 130 is pivotally fixed to mounting plte 92 via a 
pivot pin 132. Lever 130 includes a curved portion 133, which defines a 
half-circle, the midpoint of which is pivoted on pin 132. The ends of the 
curved portion 133 are connected to operate the brake shoes 116 and 118 
via links 134 and 136, respectively. The ends of link 134 are pivotally 
fixed to lever 130 and shoe 116 via pivot pins 138 and 140, respectively, 
with pin 140 being located at the opposite end of shoe 116 from its fixed 
pivot pin 120. The ends of link 136 are pivotally fixed to lever 130 and 
shoe 118 via pivot pins 142 and 144, respectively, with pin 144 being 
located at the opposite end of shoe 118 from its fixed pivot pin 122. 
Springs 146 and 148 are biasing springs, which interconnect the shoes 116 
and 118 to provide instant response upon release of the brake. This is 
important to the invention wherein the setting of the brake is desired 
during the very initial portion of travel of the electrical brake setting 
means, while permitting the remaining portion of the travel to be used for 
accomplishing other functions, to be hereinafter explained. 
Brake actuating lever 130 additionally includes an arm portion 150 bent at 
152 such that it extends from within drum 96 to the outside thereof. Its 
extreme outer end is pivotally mounted to a brake actuating rod 154 via a 
pivot pin 156. Rod 154 slidably extends through an opening in a leg 
portion 158 of an L-shaped spring mounting bracket 160. The other leg 
portion 162 is fastened to mounting plate 92 via fasteners 164. Leg 
portion 158 includes an extension 166 for coacting with a pneumatic or 
hydraulic regulator, such as a dashpot 168, as will be hereinafter 
explained. 
Thus, brake actuating rod 154 is supported on one end of brake actuating 
lever 130, and it is guided for rectilinear movement via spring mounting 
bracket 160. Rod 154 includes first and second ends 170 and 172, 
respectively. End 170 is threaded, and a main or primary spiral spring 174 
is telescoped over end 170, with one end of the spring 174 being disposed 
in a circular depression formed in the spring mounting bracket 160 about 
the opening therein which receives the rod 154. A spring collar 176 is 
disposed about rod 154, over end 170, against the other end of spring 174. 
Nuts 178 are threadably engaged with end 170, and they are advanced to 
compress spring 174 to a predetermined stored force. The preset 
compression of spring 174 determines the maximum braking force to be 
applied by the shoes 116 and 118 against the brake drum, and it is 
selected according to the width and rise of the associated escalator. It 
will be noted that compression spring 174 forces rod 154 vertically 
upward, in the view of FIG. 3, which rotates lever 130 counterclockwise 
about pivot pin 132, forcing link 136 vertically upward and link 134 
vertically downward, to pivot shoes 116 and 118 about their fixed pivot 
points to force the brake pads against surface 104 of the brake drum 96. 
Spring 174 may be compressed to a predetermined height for a specific 
width and rise of the associated escalator, and the resulting braking 
force may be checked by applying a torque wrench to the input shaft 72 of 
the gear reducer 62. 
Axial displacement of the brake actuating rod 154 in the downward 
direction, with a force sufficient to overcome the preset bias of spring 
174, will pivot lever 130 clockwise about pivot pin 132, and links 134 and 
136, aided by biasing springs 146 and 148, will draw the shoes 116 and 118 
away from drum 96, to release the brake. 
According to the teachings of the invention, a U-shaped member or yoke 180 
having an opening in the bight 182 sized to slide over end 172 of rod 154, 
is telescoped over end 172. A secondary spring arrangement 184 is disposed 
over end 172, and a spring collar 186 is fixed to end 172. The secondary 
spring arrangement 184, in this embodiment, includes a first spiral spring 
188 which extends across the complete dimension between bight 182 and 
spring collar 186, and a second spiral spring 190 disposed concentrically 
within the opening in the first spiral spring 188. The second spiral 
spring 190 has a shorter length dimension than the first spring 188. This 
two-spring arrangement provides a compound spring characteristic required 
to provide a stored force in the secondary spring arrangement 184 which 
will be capable of exceeding the stored force in the primary spring 174, 
while providing a compound spring characteristic curve which will follow 
the force curve of the electrical actuating means without exceeding the 
latter curve at any point. It is essential that the ultimate stored force 
in the secondary spring arrangement 184 exceeds the preset force in the 
primary state 174, in order to apply the brake shoes 116 and 118 to drum 
96 with substantially zero initial force when the brake 90 is applied, as 
will be hereinafter explained. It is also essential that the stored force 
in the secondary spring arrangement 184 not exceed the force versus the 
position characteristic of the electrical actuating means, in order to 
prevent the electrical actuating means from stalling before completing its 
stroke. 
The electrical actuating means may be an electromagnetic solenoid 192, 
which includes an electrical coil 194, a magnetic core 195, and a movable 
armature having arms or extensions 198. Solenoid 192 is fixed to the 
mounting plate 92 via an L-shaped mounting bracket 200 having one leg 202 
fixed to plate 92 via fasteners 204, and the other leg 206 fixed to the 
solenoid 192 via suitable fasteners (not shown). Arms 198 are linked to 
the leg portions 208 and 210 of yoke 180 via pin 212, which extends 
through aligned openings in arms 198 and legs 208 and 210. When solenoid 
192 is deenergized, the brake 90 is in the brake-applied condition shown 
in FIG. 3. When solenoid 192 is energized its armature moves vertically 
downward through a predetermined stroke, which will be assumed to be 1", 
for purposes of example, to release the brake. FIG. 4 is a fragmentary 
view of brake 90, illustrating the condition of the solenoid 192 and its 
associated actuating mechanical assembly, in the brake-released condition. 
A finger 213 may be fixed to end 170 of the actuating rod 154, in order to 
actuate a switch 215 which is fixed to the mounting plate 92. When the 
brake is released, the downward movement of rod 154 causes finger 213 to 
actuate switch 215. Actuation of switch 215 indicates to the escalator 
control that the brake has released and that drive power may be applied to 
the escalator drive mechanism. 
As hereinbefore explained, the primary spring 174 is preloaded to a 
predetermined stored force when the brake is set, with this value being 
determined by the width and rise of the escalator. For example, for a 48" 
wide stairway, the preload is 35# for a 12' rise, 55# for an 18' rise, and 
75# for a 25' rise. The long secondary spring 188 has from 0 to 5 pounds 
preload force when the brake is set, and the short secondary spring 190 is 
unloaded. When the solenoid 192 is energized to release the brake, the 
solenoid starts its stroke by compressing first the long secondary spring 
188, and then both the long and short secondary springs. Rod 154 does not 
move during this time, remaining stationary until the force stored in the 
secondary springs exceeds the preload force stored in the primary spring 
174. When the force stored in the secondary springs exceeds the preload of 
the primary spring, the primary and secondary springs will all be 
compressed simultaneously and rod 154 will now be displaced downwardly, to 
release the brake. 
FIG. 5 graphically illustrates the release of the brake 90 for a solenoid 
192 having a 1" stroke. Curve 220 plots the force available from a 
selected solenoid, versus stroke position. The specific solenoid used had 
a pull-in voltage of 125 volts D.C. at 2.5 amperes. The holding voltage 
was 24 volts D.C. at 0.5 amperes. Curve 222 illustrates the force 
characteristic curve of the long secondary spring 188. Curve 224 
illustrates the force characteristic curve of the short secondary spring 
190. Curve 226 illustrates the preload on the primary spring 174. Curve 
228 is the resulting composite force versus stroke curve for the spring 
arrangement shown in FIGS. 3 and 4. 
When the brake is set, the force stored in the secondary springs is 
substantially zero, and the primary spring is at the preload force. When 
the brake is to be released, the solenoid starts its stroke by compressing 
the long secondary springs, it then compresses the long and short 
secondary springs, and when the force stored in the secondary springs 
equals the preload of the primary spring, it compresses the primary and 
secondary springs. Thus, when the brake is in the released condition, the 
force stored in the primary spring is slightly greater than its preload 
force, and the force stored in the secondary springs is slightly greater 
than the force stored in the primary spring. The difference between the 
stored force of the primary spring, and the stored force of the secondary 
springs, is slight. 
When solenoid 192 is deenergized, the armature is not allowed to travel 
through its stroke solely under the influence of the primary and secondary 
springs. It is critical to the invention that the force applied by the 
brake shoes against the brake drum, during the setting of the brake, be 
equal to the arithmetic difference between the forces stored in the 
primary and secondary springs. Thus, the secondary spring arrangement 184 
must react against yoke 180 to force rod 154 downwardly, while primary 
spring 174 is reacting against the fixed spring seat 158 to force rod 154 
upwardly. Then, by controlling the position of yoke 180 to allow the 
secondary spring arrangement to decompress according to a predetermined 
schedule, the brake shoe force pattern and thus the jerk and deceleration 
of the escalator may be controlled to follow predetermined curves. 
In the embodiment of the invention shown in FIGS. 3 and 4, the yoke 180 and 
thus the position of the solenoid armature versus time, is controlled by a 
viscous damping device such as dashpot 168. Dashpot 168 has one portion, 
such as the cylinder portion 240, fixed to yoke 180. Its other portion, 
such as the piston portion 242, contacts extension 166 which is part of 
the fixed spring seat bracket 160. Dashpot 168 may be a type which 
provides controlled movement in only one direction, such as illustrated in 
FIG. 3, wherein the piston is spring biased to the position shown in FIG. 
4 when the brake is released. The dashpot 168 then controls the movement 
of yoke 180 from the FIG. 4 position to the FIG. 3 position. Or, as 
illustrated in FIG. 6, which is a fragmentary view of dashpot 168, 
referenced 168' in order to indicate the modification thereof, the piston 
242' may have its outer end fixed to a fixed bracket 244 which is fastened 
to mounting plate 92. In the arrangement of FIG. 6, dashpot 168' will 
cushion the pick-up of the solenoid 192, in addition to controlling the 
setting of the brake 90. 
Returning to the graph of FIG. 5, when the solenoid is deenergized, the 
secondary spring arrangement 184 works against the yoke 180, which in turn 
is controlled by dashpot 168. The first part of the travel of the solenoid 
armature and yoke 180, such as about 0.25 inch, allows both the primary 
spring 174 and the secondary spring arrangement 184 to start to 
decompress, and rod 154 is displaced upwardly to the point where the brake 
shoes 116 and 118 contact the brake drum 96. This initial contact is made 
with very little force, i.e., the difference between the stored forces in 
the primary and secondary spring arrangements. Further movement of the 
solenoid armature and yoke 180 allows decompression of the secondary 
spring arrangement 184, but the primary spring 174 will not decompress 
beyond its preset load, as the shoes are now in contact with the brake 
drum, and lever 130 and rod 154 thus have reached their travel limits. The 
force of the shoes against the drum, however, continues to increase in a 
controlled manner as the secondary spring arrangement continues to 
decompress as the dashpot allows the solenoid armature to continue its 
controlled stroke. The secondary spring force curve 228 follows a first 
segment 234 until the stored spring force drops below the preset primary 
spring force, and then it follows a segment 232 which is a composite curve 
formed by the characteristics 222 and 224 of the long and short secondary 
springs 188 and 190, respectively. When the short secondary spring is no 
longer compressed, the characteristic curve follows a segment 230 which is 
part of the long secondary spring characteristic curve 222. Curve segments 
232 and 230 subtract from the preset value of curve 226 at each position 
of the solenoid armature to determine the brake shoe force at each 
armature position. Curve 228 is valid for any setting of the dashpot 168, 
as it is a force versus stroke curve, and not a force versus time curve. 
FIG. 7 is a graph which plots braking force of the brake shoes against the 
brake drum versus time. Curves 250, 252 and 254 illustrate different 
dashpot settings. Curve 256 illustrates the type of braking curve which 
would occur without the use of the secondary spring arrangement 184. If 
the secondary spring arrangement 184 were to be eliminated, the braking 
force would immediately increase to its maximum value, and then the 
braking force would be constant. The present invention prevents this 
infinite jerk from occurring upon initial brake application, and it 
controls the deceleration rate to cause it to reach the maximum value in 
response to the arithmetic difference in the spring portions of the 
primary and secondary spring arrangements. 
From curve 228, it will be noted that the position of the solenoid armature 
controls the braking torque. It will also be noted that the secondary 
spring characteristic curve 228 reaches and exceeds the preset primary 
spring portion 226 without exceeding the force available in the solenoid, 
i.e., curve 220, at any stroke position. This is important, as the 
solenoid must not be stalled by the spring arrangement. For lower preloads 
on the primary spring 174, it may be possible to utilize a single 
secondary spring. 
Instead of controlling the position of the solenoid armature by the dashpot 
168 during the setting of the brake, the current in the solenoid coil 194 
may be controlled to control the solenoid position. The current may be 
controlled in an open-ended manner, to function as an electrical dashpot, 
or it may be controlled according to escalator speed, to cause the 
escalator to decelerate and stop according to a predetermined deceleration 
schedule, which would decelerate a down traveling escalator in precisely 
the same manner from full load to no load on the escalator. However, even 
when the solenoid current is being controlled, a dashpot of some sort may 
still be utilized, to provide damping. The dashpot in this instance would 
have a different characteristic than the dashpot 168. 
In a feedback type of arrangement, a pickup 260 may be disposed on mounting 
base 92, adjacent to the teeth 108 formed on the outer surface 106 of drum 
96. Pickup 260, which may be of the magnetic type, or any other suitable 
type, will provide pulses, with each pulse being an indication of a 
predetermined increment of escalator travel. The pulse rate will be an 
indication of the escalator speed. As shown in FIG. 8, the pickup 260 may 
be connected to a pulse generator 262, which shapes the pulses from the 
pickup 260. The pulses from pulse generator 262 are applied to a pulse 
rate-to-voltage converter 164. The output from converter 264 is an analog 
signal, which is applied to one input of a summing junction 266. 
A desired deceleration speed pattern may be programmed into a read only 
memory (ROM) 268. The output of memory 268 is connected to a 
digital-to-analog converter 270, and converter 270 provides an analog 
speed pattern signal, which is applied to the remaining input of the 
summing junction 266. 
When the escalator control 272 indicates the escalator should decelerate 
and stop, and elevator drive power to the drive motor is cut off, a signal 
is provided which enables the pulse generator to generate output pulses 
for the converter 264 and the memory or pattern generator 268. The pattern 
generator 268 starts at a value responsive to normal escalator speed, and 
each pulse clocks a counter which addresses the memory 268, with each 
succeeding address or count causing memory 268 to provide a new, lower 
output for the new position of the escalator. Thus, the memory 268 
indicates the desired speed for each position increment which occurs 
following the decision to stop the escalator. Summing junction 266 
provides a signal responsive to any differene between the actual and 
desired speeds. Error amplifier 274 amplifies the difference signal, and 
this error signal is applied to solenoid current controller 276. Solenoid 
current controller 276 controls the voltage applied to the brake solenoid 
coil 194, and thus the current flowing in the solenoid coil is controlled. 
A ROM speed feedback control system is disclosed in U.S. Pat. No. 
4,102,436, which is assigned to the same assignee as the present 
application. Of course, other suitable speed feedback arrangements may be 
used. 
Brake 90, as described to this point, will thus apply a braking force with 
very little jerk, and it will cause the braking force to smoothly build to 
the maximum value, maintaining the rate of change of deceleration or jerk 
below a predetermined low value, such as 6 ft/sec.sup.3. Thus, a 
downwardly traveling escalator will be smoothly decelerated and stopped 
according to the same deceleration schedule, regardless of load. 
The inertia of the escalator and the passenger load will stop an up 
traveling escalator. If the brake 90 were to apply the same braking force 
to an upwardly traveling escalator as it does to a downwardly traveling 
escalator, the stop of an upwardly traveling escalator may be very abrupt, 
especially when loaded. The present invention solves this problem without 
requiring any feedback information as to which direction the escalator is 
traveling when the brake is applied, by inherently braking the escalator 
with different braking efforts in the two travel directions. To accomplish 
this, the brake shoes 116 and 118 are purposely arranged to be 
self-energizing when the escalator is traveling in the downward direction, 
i.e., to transport passengers from an upper to a lower landing, and 
partially deenergizing in the up-travel direction. In other words, when 
the drum 96 is rotating such that the escalator is traveling downwardly, 
the mounting arrangement of the brake shoes automatically makes them the 
leading shoe type wherein the direction of drum rotation helps apply the 
braking actuation forces. When the brake drum is rotating in the opposite 
direction, the shoes are automatically of the trailing type wherein the 
drum rotation reduces the braking actuation force. This is schematically 
illustrated in FIG. 9, with brake shoe 116 being illustrated mounted in 
brake drum 96. The explanation for brake shoe 118 would be similar to that 
of 116, and thus brake shoe 118 is not illustrated. Arrow 280 indicates 
drum rotation for a downwardly traveling escalator. When the brake 90 is 
set or applied, the actuating force P, illustrated by arrow 282, applies a 
normal force N to the brake shoe 116, indicated by arrow 284, which in 
turn provides the friction force F, indicated by arrow 286. The friction 
force F is equal to the coefficient of friction .mu. multiplied by the 
normal force N, i.e., (F=.mu.N). The friction force F tends to rotate the 
brake shoe 116 counterclockwise about the center 288 of brake drum 96, 
which increases the normal force N, which increases the friction force F, 
which again increases the normal force N, etc. The increase in the normal 
force is proportional to the friction force F multiplied by the ratio of 
the distance b, i.e., the perpendicular distance of force F to the pivot 
pin 120 to the distance a, i.e., the perpendicular distance of the normal 
force N to the pivot pin 120. Thus, if N.sub.1 is equal to the increase in 
the normal force: 
EQU N.sub.1 =Fb/a (1) 
If F.sub.1 is the added friction force: 
EQU F.sub.1 =UN.sub.1 =UFb/a (2) 
This self-energizing action is cumulative so that the total friction force 
F.sub.T is: 
EQU F.sub.T =F[1+U b/a+(Ub/a).sup.2 + . . . (Ub/a).sup.N ] (3) 
The factor within the brackets of equation (3) is called the energy factor. 
The quantity Ub/a must be less than unity in order to prevent the brake 
from being selflocking. 
Angle .theta. in FIG. 9 is the included angle between the average normal 
force N and a line drawn through the shoe pivot axis and the drum center 
288. With an angle .theta. of 68.degree. and a coefficient of friction 
.mu. of 0.4, the brake torque will be relatively stable for changes in 
.mu. and in the angle .theta. as the brake shoes seat themselves into full 
contact with the brake drum. To further control initial and subsequent 
contact of the shoes with the brake drum, the brake shoes are designed 
with a smaller radius than the brake drum, as hereinbefore pointed out. 
This causes the brake shoes to contact at their midpoint leaving a small 
clearance to the drum at both ends of the shoes. This clearance can 
readily be checked during manufacture with a feeler gage through windows 
in the brake drum. 
As the shoes progressively "seat-in" the angle .theta. will increase to 
85.degree. maximum and then finally move back to 68.degree. when the shoes 
are fully seated. 
FIG. 10 is a chart which plots the force P versus angle .theta., and the 
energy factor EF versus the angle .theta., for different values of the 
coefficient of friction .mu., assuming a brake drum having a diameter of 
8", and a brake torque of 1000 in. #. Note that as the angle .theta. 
changes from 68.degree. to 85.degree., and then moves back again to 
68.degree., that the energy factor EF increases from the 68.degree. value. 
Thus, any change in brake torque during seating-in, is an increase in 
brake torque, which is desirable. 
For an up traveling escalator, the brake action is opposite to that 
described for a downwardly traveling escalator, and the braking action is 
partially deenergizing. In this instance, the brake force F tends to 
rotate the brake shoe 116 clockwise, which reduces the normal force. A 
brake having an energy factor of 1.5 in the downward direction, would only 
have an energy factor of 0.66 in the upward direction. Thus, if the brake 
torque is 1000 in. pounds in the downward travel direction, it would be 
reduced to only 440 in. pounds in the upward travel direction. 
Thus, there has been disclosed a new and improved brake, which is 
especially suitable for escalators. The brake inherently brakes with a 
greater braking force when the escalator is traveling downwardly, than 
when it is traveling upwardly. Further, the brake shoes are initially 
applied to the brake drum with very little force, and the braking force is 
allowed to build according to a predetermined deceleration schedule, in 
order to maintain jerk at a very low level.