08PM62 Drive Power and Torque in Papermachine Dryers en

Drive Power and Torque in Papermachine Dryers
Gerald L. Timm, VP Research and Development, Kadant Johnson
Mikeal D. Skelton, Research Process Engineer, Kadant Johnson
Gregory L. Wedel, Corporate VP Technology, Kadant Johnson
ABSTRACT
A basic parameter in the design of a paper machine dryer drive system, whether it has an open gear, enclosed gear,
or felt drive, is the drive power requirement. Previous work on the drive power for paper machine dryers covered a
1.5 meter diameter cylinder. This paper presents the results for both 1.5 and 1.83 meter diameter cylinders with and
without dryer bars. Torque, as well as power, is an important aspect in designing and operating a modern dryer
section drive. The torque and power required to drive a dryer increases significantly as the amount of condensate in
the dryer increases. The torque is greatly reduced when the condensate passes into the rimming condition. Dryer
bars significantly reduce the speed at which the condensate rims and decrease the power and the torque required to
make this transition. These results are presented along with information on the observed behavior of the condensate
inside the dryer under a wide range of operating conditions. This information will help in predicting the drive power
and drive torque that is required in the commercial operation of paper machine dryers.
Introduction
The power required to drive a dryer section of a conventional paper machine must overcome the following:
-
Mechanical inertia, particularly of dryer and felt rolls
Aerodynamic drag, particularly associated with dryer fabrics and rolls
Fabric flexing, which depends on fabric design and tension and roll diameters*
Rotary joint friction, which depends on dryer speed, joint design, number of joints, and steam pressure*
Web tension, particularly following or preceding draw locations*
Dryer doctor friction, which depends on speed, dryer surface condition, blade load, and blade material*
Threading rope drag, particularly if the ropes are stretched in draws*
Blow box and ventilator seals, particularly those that contact the dryer fabrics*
Ventilation roll seals, which depend on the seal material, seal load, and dryer speed*
Dryer drive gears and gear boxes (spur, helical, lubricated or dry)*
Dryer and felt roll bearings, greased or continuous lubrication*
Fabric guide rolls, particularly when there is fabric distortion*
Dryer syphons, both rotating and stationary types
Condensate behavior, which depends on the dryer speed, the amount of condensate in the dryer, the speed
history, and the use of dryer bars
The drive power associated with the above items marked with an asterisk typically increases directly with dryer
speed. For the others, the drive power increases with the square of the dryer speed. As a result, the drive power for
a conventional dryer section increases with some power of speed that is greater than 1 but less than 2.
This paper is focused on testing to quantify the dryer drive power associated with the condensate behavior.
Condensate in a dryer cylinder has three stages of behavior that depend on speed. At slow speeds, condensate forms
a puddle at the bottom of the cylinder. In this stage, the power consumption is low. As the speed increases, the
puddle moves in the direction of rotation and widens. As the speed is further increased, the second stage occurs as
the trailing edge of the puddle extends over the horizontal centerline of the cylinder and condensate cascades back to
the bottom of the cylinder. The height to which the condensate rises before it cascades increases with the cylinder
speed, as does the flow rate of the condensate that cascades. The combination of the increasing elevation and
increasing flow causes a quadratic increase in the power required as speed increases. The final stage occurs as speed
is increased further, and the condensate forms a rimming layer on the inner surface of the cylinder. Power
consumption in this stage is much lower. These three stages of condensate behavior are shown in Figure 1.
Puddling
Cascading
Rimming
Figure 1. Three Stages of Condensate Behavior
As speed is decreased, the rimming condensate film will collapse and the condensate will return to a cascade and
eventually back to a puddle. The speed at which the condensate rim collapses is less than the speed at which the rim
was established.
Dryer Drive Power Tests
The dryer drive power and torque were determined using the Kadant Johnson Joco 4000 and Joco 6000 pilot dryers
at the W. R. Monroe Research Center in Three Rivers Michigan. The Joco 4000 and Joco 6000 are commercial
paper machine dryers, with nominal diameters of 1.5 m (60”) and 1.8 m (72”), respectively. They each have
commercial face widths: 6.35 m (250”) and 8.81 m (347”) and are capable of operating at speeds up to 1520 mpm
(5000 fpm) and 2000 mpm (6560 fpm), respectively. Both dyers have condensate grooves near the heads allowing
for testing of both rotating and stationary siphons, located in and outside siphon grooves. For these tests, the
grooves were filled with steel rings to simulate cylinders without siphon grooves. Testing with the grooves unfilled
was reported in a previous paper (5)
For each test condition, a measured amount of water was placed in the dryer and the dryer speed was slowly
increased to a maximum and then slowly decreased back to a stop, measuring the drive torque continuously. Tests
were conducted with and without dryer bars in the dryers. The very slow acceleration and deceleration rates
eliminated the dryer inertial load and helped to give more definition to the resulting drive load curves.
The data presented here covers the power and torque requirements for a wide range of dryer speeds, with the water
going from puddling, through cascading, to rimming conditions. The speeds at which the condensate rims and
collapses from the rim were determined for each of the various amounts of condensate in the dryer.
Dryer Drive Power
In the first series of tests, the dryers were operated without dryer bars. The amount of condensate (water) in the
dryers was varied from an equivalent rim depth of 1.6 mm (0.063”) to 12.7 mm (0.5”). In the second series of tests,
dryer bars were installed in the cylinders. The dryer bars used for these tests were Kadant Johnson Turbulator®
Tube™ bars. These bars are 15 mm in height and 25 mm in width. They are equally spaced around the inside
surface of the dryer, to generate resonant oscillation of the condensate layer. This oscillation increases the rate and
cross-machine uniformity of heat transfer.
The drive power is shown in Figure 2 for each of five different amounts of condensate in the 1.5 m diameter dryer
and in Figure 3 for the 1.8 m diameter dryer. The drive power is listed in kW per meter of dryer face width. The
condensate amounts are listed as the “equivalent” rimming film thickness, that is, the thickness calculated as if the
condensate were distributed in an even film on the dryer inside surface.
As the dryer speed increases, the condensate moves from puddling, to cascading, then to rimming. The drive power
increases quadratically until the condensate beings to rim. At that point, the drive power decreases substantially.
Figures 2 and 3 show four important points. The power required to pass through cascading into rimming increases
as the amount of condensate in the dryer increases. Secondly, the speed at which the peak power consumption
occurs increases as the amount of condensate in the dryer increases. Thirdly, when the condensate is rimming, the
power required to drive the dryer is not significantly influenced by the amount of condensate, even when the
rimming depth is as large as 12.7 mm. Note that for a given condensate thickness, condensate in the 1.8 meter
diameter cylinder rims at a higher speed and requires more power than condensate in the 1.5 meter diameter
cylinder.
3.0
12.7 mm rim layer
2.5
9.5 mm rim layer
Power, kW/m
6.4 mm rim layer
2.0
3.2 mm rim layer
1.6 mm rim layer
1.5
1.0
0.5
0.0
0
500
1000
1500
2000
Dryer Speed, m/min
Figure 2. Dryer Drive Power versus Dryer Speed
1.5 meter diameter dryer, without dryer bars
3.0
12.7 mm rim layer
2.5
9.5 mm rim layer
Power, kW/m
6.4 mm rim layer
2.0
3.2 mm rim layer
1.6 mm rim layer
1.5
1.0
0.5
0.0
0
500
1000
1500
Dryer Speed, m/min
Figure 3. Dryer Drive Power versus Dryer Speed
1.8 meter diameter dryer, without dryer bars
2000
Figures 4 and 5 show similar data for the dryers with dryer bars. These figures show that, for a dryer with bars, the
power required to pass through the cascading condition into the rimming condition also increases as the amount of
condensate in the dryer increases and that the speed at which the peak power occurs increases as the amount of
condensate in the dryer increases. The power required to drive a dryer with dryer bars and rimming condensate is
not significantly influenced by the amount of condensate in the dryer.
3.0
12.7 mm rim layer
2.5
9.5 mm rim layer
Power, kW/m
6.4 mm rim layer
2.0
3.2 mm rim layer
1.6 mm rim layer
1.5
1.0
0.5
0.0
0
500
1000
1500
2000
Dryer Speed, m/min
Figure 4. Dryer Drive Power versus Dryer Speed
1.5 meter diameter dryer, with dryer bars
3.0
12.7 mm rim layer
9.5 mm rim layer
2.5
Power, kW/m
6.4 mm rim layer
2.0
3.2 mm rim layer
1.6 mm rim layer
1.5
1.0
0.5
0.0
0
500
1000
1500
2000
Dryer Speed, m/min
Figure 5. Dryer Drive Power versus Dryer Speed
1.8 meter diameter dryer, with dryer bars
A comparison of Figure 2 to Figure 4, and Figure 3 to Figure 5, shows that condensate in a dryer with dryer bars will
rim at a much lower speed than condensate in a dryer without dryer bars. Furthermore, the drive power at which this
transition occurs is much less in a dryer with dryer bars than in a dryer without dryer bars.
Dryer Torque
Figures 6 and 7 show the drive torque (in N-m per meter of dryer width) for the 1.5 m and 1.8 m diameter dryers,
respectively, without bars in the dryers. These figures show that the drive torque required to pass through the
cascading condensate condition into the rimming condensate condition increases as the amount of condensate in the
dryer increases, and the speed at which the peak torque occurs increases as the amount of condensate in the dryer
increases. Once the condensate is rimming, the drive torque increases only slightly with speed.
250
12.7 mm rim layer
9.5 mm rim layer
200
Torque, N-m/m
6.4 mm rim layer
3.2 mm rim layer
150
1.6 mm rim layer
100
50
0
0
500
1000
1500
2000
Dryer Speed, m/min
Figure 6. Dryer Drive Torque versus Dryer Speed
1.5 meter diameter dryer, without dryer bars
250
12.7 mm rim layer
9.5 mm rim layer
200
Torque, N-m/m
6.4 mm rim layer
3.2 mm rim layer
150
1.6 mm rim layer
100
50
0
0
500
1000
1500
Dryer Speed, m/min
Figure 7. Dryer Drive Torque versus Dryer Speed
1.8 meter diameter dryer, without dryer bars
2000
Figures 8 and 9 show similar torque data for the dryers with dryer bars. For a dryer with dryer bars, the drive torque
required to pass through the cascading condensate condition into the rimming condensate condition increases as the
amount of condensate in the dryer increases. Furthermore, the speed at which the peak torque occurs increases as the
amount of condensate in the dryer increases. With the dryer bars in the dryer, the drive torque is only slightly
affected by the amount of condensate in the dryer, once the condensate is rimming.
250
12.7 mm rim layer
9.5 mm rim layer
200
Torque, N-m/m
6.4 mm rim layer
3.2 mm rim layer
150
1.6 mm rim layer
100
50
0
0
500
1000
1500
2000
Dryer Speed, m/min
Figure 8. Dryer Drive Torque versus Dryer Speed
1.5 meter diameter dryer, with dryer bars
250
12.7 mm rim layer
9.5 mm rim layer
200
Torque, N-n/m
6.4 mm rim layer
3.2 mm rim layer
150
1.6 mm rim layer
100
50
0
0
500
1000
1500
2000
Dryer Speed, m/min
Figure 9. Dryer Drive Torque versus Dryer Speed
1.8 meter diameter dryer, with dryer bars
Data from the previous figures is presented in cross-plots in Figures 12-19 for rimming speed, collapsing speed, and
peak torque. In these cross-plots, rimming speed is defined as the lowest recorded speed (during the increasing speed
test) at which the reduction in the dryer drive power and torque was complete. Collapsing speed is defined as the
highest recorded speed (during the decreasing speed test) at which the increase in the dryer drive power and torque
was complete. In between the rimming speed and the collapsing speed, the condensate may be either rimming or
cascading, depending on the speed history of the dryer cylinder, as shown in Figures 10 and 11.
3.0
Peak Power
Increasing speed
2.5
Decreasing speed
Power, kW/m
2.0
Collapsing Speed
1.5
Rimming Speed
1.0
0.5
0.0
0
200
400
600
800
1000
1200
1400
Dryer Speed, m/min
Figure 10. Dryer Drive Power versus Dryer Speed
1.5 meter diameter dryer, 12.7 mm rim layer, without dryer bars
3.0
Increasing speed
2.5
Decreasing speed
Power, kW/m
2.0
1.5
1.0
0.5
0.0
0
200
400
600
800
1000
1200
Dryer Speed, m/min
Figure 11. Dryer Drive Power versus Dryer Speed
1.5 meter diameter dryer, 12.7 mm rim layer, with dryer bars
1400
800
Rimming
Dryer Speed, m/min
600
Transition
400
Cascading
200
speed to rim - calculated
speed at peak torque - calculated
speed for rim collapse - calculated
speed to rim - observed
speed at peak torque - observed
speed for rim collapse - observed
0
0
2
4
6
8
10
12
14
Rim Layer Thickness - mm
Figure 12. Speed and Condensate Behavior
1.5 meter diameter dryer, without dryer bars
For cylinders without bars, the difference between the rimming and collapsing speeds increases with increasing
condensate film thickness. The speed at which the maximum torque was observed is about 90-95% of the rimming
speed. The torque load rapidly decreases at speeds between 90% and 100% of the rimming speed. Figures 11 and
12 show the cross plots for the 1.5 and 1.8 meter cylinders respectively.
800
Rimming
Dryer Speed, m/min
600
Transition
400
Cascading
200
speed to rim - calculated
speed at peak torque - calculated
speed for rim collapse - calculated
speed to rim - observed
speed at peak torque - observed
speed for rim collapse - observed
0
0
2
4
6
8
10
Rim Layer Thickness - mm
Figure 13. Speed and Condensate Behavior
1.8 meter diameter dryer, without dryer bars
12
14
400
Rimming
Dryer Speed, m/min
300
200
Transition
Cascading
100
speed to rim - calculated
speed at peak torque - calculated
speed for rim collapse - calculated
speed to rim - observed
speed at peak torque - observed
speed for rim collapse - observed
0
0
2
4
6
8
10
12
14
Rim Layer Thickness - mm
Figure 14. Speed and Condensate Behavior
1.5 meter diameter dryer, with dryer bars
Figures 14 and 15 show the cross plots of rimming and cascading speeds for cylinders with dryer bars. These speeds
are lower than the speeds for dryers without bars. The difference between rimming and cascading speeds decreases
with increasing condensate film thickness. Further, the rimming speed for a cylinder with bars is much smaller than
for a cylinder without bars. The peak torque load with bars occurs at about 50% to 80% of the rimming speed
depending on condensate film thickness.
400
Rimming
Dryer Speed, m/min
300
Transition
200
Cascading
100
speed to rim - calculated
speed at peak torque - calculated
speed for rim collapse - calculated
speed to rim - observed
speed at peak torque - observed
speed for rim collapse - observed
0
0
2
4
6
8
10
Rim Layer Thickness - mm
Figure 15. Speed and Condensate Behavior
1.8 meter diameter dryer, with dryer bars
12
14
Figures 16 and 17 compare the rimming and collapsing speeds for the 1.5 and 1.8 meter diameter cylinders with and
without bars respectively. Again, both rimming speeds and collapsing speeds are significantly reduced with bars.
800
No bars
Dryer Speed, m/min
600
Dryer bars
400
200
1.5 meter dryer, with bars - calculated
1.8 meter dryer, with bars -calculated
1.5 meter dryer, no bars - calculated
1.8 meter dryer, no bars - calculated
1.5 meter dryer, with bars - observed
1.8 meter dryer, with bars - observed
1.5 meter dryer, no bars - observed
1.8 meter dryer, no bars - observed
0
0
2
4
6
8
10
12
14
Rim Layer Thickness - mm
Figure 16. Dryer Rimming Speed versus Rim Layer Thickness
500
1.5 meter dryer, with bars - calculated
1.8 meter dryer, with bars -calculated
1.5 meter dryer, no bars - calculated
1.8 meter dryer, no bars - calculated
Dryer Speed, m/min
400
1.5 meter dryer, with bars - observed
1.8 meter dryer, with bars - observed
1.5 meter dryer, no bars - observed
1.8 meter dryer, no bars - observed
300
No bars
200
Dryer bars
100
0
0
2
4
6
8
10
12
14
Rim Layer Thickness - mm
Figure 17. Dryer Rim Collapsing Speed versus Rim Layer Thickness
Figure 18 shows that the peak drive power is approximately 50% lower in dryers with dryer bars than in dryers
without dryer bars. This can be very important, particularly in dryers with low drive capacity. The reduction in
drive power is most significant with large rimming depths (a large amount of residual condensate).
4
1.5 meter diameter dryer, no bars observed
1.5 meter diameter dryer, no bars calculated
1.5 meter diameter dryer, with bars observed
1.5 meter diameter dryer, with bars calculated
1.8 meter diameter dryer, no bars observed
1.8 meter diameter dryer, no bars calculated
1.8 meter diameter dryer, with bars observed
1.8 meter diameter dryer, with bars calculated
Power, kW/m
3
No bars
2
1
Dryer bars
0
0
2
4
6
8
10
12
14
Rim Layer Thickness, mm
Figure 18. Peak Power versus Film Thickness
Dryers with and without dryer bars
Figure 19 shows that the peak torque is also less with dryer bars than in a cylinder without dryer bars, provided both
of the dryers have the same amount of condensate.
400
1.5 meter diameter dryer, no bars observed
1.5 meter diameter dryer, no bars calculated
1.5 meter diameter dryer, with bars observed
1.5 meter diameter dryer, with bars calculated
1.8 meter diameter dryer, no bars observed
1.8 meter diameter dryer, no bars calculated
1.8 meter diameter dryer, with bars observed
1.8 meter diameter dryer, with bars calculated
Torque, N-m/m
300
No bars
200
100
Dryer bars
0
0
2
4
6
8
10
Rim Layer Thickness, mm
Figure 19. Peak Torque versus Film Thickness
Dryers with and without dryer bars
12
14
Analytical Models
In 1958, White and Higgins (2) published a correlation for rimming speed based on dimensional analysis and data
from a 0.305 meter diameter cylinder without bars. The rimming speeds observed in the 1.5 meter diameter and 1.8
meter diameter cylinder testing were somewhat higher than predicted from their analysis. This is primarily because
White and Higgins defined “rimming speed” as the point of peak power and torque, rather than the point at which
the transition to rimming was complete.
Following White and Higgins, a correlation was applied to the above data resulting in the following equation:
V = 12.4 (δ g ) 0.5 ( R / δ ) 0.18 (δ 3 g /ν 2 ) 0.013
(1)
where R is the dryer inside radius, δ is the rimming film thickness, ν is the kinematic viscosity, g is the gravitational
acceleration, and V is the rimming speed of the inner surface. The exponent on the dimensionless group with the
fluid properties could not be established from these tests, since the fluid properties did not vary. The exponent
established by White and Higgins (2) was used instead.
A similar correlation can be applied to the collapsing speed:
C = 2.0 (δ g ) 0.5 ( R / δ ) 0.452 (δ 3 g /ν 2 ) 0.013
(2)
where C is the speed at which the condensate rim collapses back into a cascade.
For a cylinder equipped with dryer bars, the equations are:
V = 2.9 (δ g ) 0.5 ( R / δ ) 0.362 (δ 3 g /ν 2 ) 0.013
(3)
and
C = 7.1 (δ g ) 0.5 ( R / δ ) 0.107 (δ 3 g /ν 2 ) 0.013
(4)
Note that all of the testing was performed at a constant initial water temperature (21°C) and therefore the second
dimensionless group only varied with the film thickness.
The data shown in Figures 12 through 17 include these correlation curves for rimming and collapsing speed (but not
for the peak power speed).
Just prior to rimming, condensate in the cylinder is, in effect, lifted from the bottom of the dryer up to the top of the
dryer where it cascades. If the entire volume of condensate is lifted to the horizontal centerline of the cylinder axis
each revolution, the power required can be estimated by the following equation:
Pp = 4 γ δ R V p
(5)
where γ is the weight density, δ is the film thickness, Vp is the dryer speed at peak power, R is the cylinder radius,
and Pp is the peak drive power expressed per unit of dryer face width.
Condensate behavior in the dryer deviates from this simple model in three ways: First, some of the condensate is
lifted above the horizontal centerline. Second, there is some portion of the condensate film which does not cascade,
but remains in a rim at higher speeds. And third, some of the condensate does not fall all the way back to the bottom
of the cylinder, but impacts the opposite side above the cylinder floor. The above equation, however, can be
combined with Equation (1) for rimming speed to provide the format for developing a correlation for the peak
power. The resulting equation for a dryer without dryer bars is given below.
Pp = γ δ R (δ g ) 0.5 ( R / δ ) 0.41 (δ 3 g /ν 2 ) 0.013 / 1098
(6)
From Figures 2 and 3, it is clear that the drive power for dryers without bars is proportional to the square of the
dryer speed, for dryers that are operating below the condensate rimming speed. The drive power can therefore be
estimated at any speed up to rimming by the following equation:
P = Pp ( S / V ) 2
(7)
where S is less than or equal to the rimming speed Vp.
At speeds above rimming, the power for a cylinder without bars can be seen from Figures 2 and 3 to also be
proportional to the square of the dryer speed. The drive power for a dryer with rimming condensate can therefore be
estimated by the following correlation equation:
P = (0.4 × 10 −6 ) S 2
(8)
where the drive power is expressed in kW per meter of face width and S is the dryer speed expressed in m/min.
This estimate for drive power is comparable to a Normal Running Load (NRL) factor, in that it excludes dryer and
felt roll inertia, web tension, and dryer doctor drive loads. It does, however, also exclude the drive load associated
with felt rolls, dryer fabrics, rotary steam joints, threading ropes, and gearboxes.
Figures 20 and 21 show a comparison between the calculated values of drive power and drive torque and the
measured values for a 1.8 meter diameter cylinder without bars and with a 6.4 mm condensate film.
1.8
1.6
Power, kW/m
1.4
1.2
1.0
0.8
0.6
0.4
Power - observed
0.2
Power - calculated
0.0
0
500
1000
1500
2000
Dryer Speed, m/min
Figure 20. Comparison of calculated power and observed data
1.8 meter diameter dryer, 6.4 mm rim layer, no dryer bars
2500
180.0
Torque - observed
160.0
Torque - calculated
Torque, N-m/m
140.0
120.0
100.0
80.0
60.0
40.0
20.0
0.0
0
500
1000
1500
2000
2500
Dryer Speed, m/min
Figure 21. Comparison of calculated torque and observed data
1.8 meter diameter dryer, 6.4 mm rim layer, no dryer bars
For a cylinder equipped with dryer bars, the peak power can also be correlated using the format of Equation (3)
combined with Equation (5). The resulting correlation equation for a dryer with dryer bars is given below:
Pp = γ δ R (δg ) 0.5 ( R / δ ) 0.463 (δ 2 g /ν 2 ) 0.013 / 2780
(9)
When the dryer has bars, the drive power for dryers operating below the rimming speed can also be approximated as
proportional to the square of the dryer speed, as seen in Figures 4 and 5. The drive power can therefore be estimated
at speeds up to rimming by Equation (7):
P = Pp ( S / V ) 2
(10)
where S is less than or equal to the rimming speed Vp.
At speeds above rimming, the power for a cylinder with dryer bars can be estimated by the following equation:
P = (0.5 × 10 −3 ) S
(11)
where the drive power is expressed in kW per meter of face width and S is the dryer speed expressed in m/min. Note
that the drive power for a dryer with bars is linearly related to speed, whereas the drive power for a dryer without
bars was related to the square of the dryer speed.
Figures 22 and 23 show a comparison of the calculated and measured values of power and torque using the above
equations for a dryer with bars.
0.9
0.8
Power, kW/m
0.7
0.6
0.5
0.4
0.3
0.2
Power - observed
0.1
Power - calculated
0.0
0
200
400
600
800
1000
1200
1400
1600
Dryer Speed, m/min
Figure 22. Comparison of calculated power and observed data
1.5 meter diameter dryer, 9.5 mm rim layer, with dryer bars
140.0
Torque - observed
120.0
Torque - calculated
Torque, N-m/m
100.0
80.0
60.0
40.0
20.0
0.0
0
200
400
600
800
1000
1200
1400
1600
Dryer Speed, m/min
Figure 23. Comparison of calculated torque and observed data
1.5 meter diameter dryer, 9.5 mm rim layer, with dryer bars
Torque for a cylinder without bars at above rimming speeds increases with speed while the torque for a cylinder
with bars is nearly constant.
SUMMARY
This paper highlights the difference in the condensate rimming speed for paper dryers operating with and without
Turbulator bars. The paper also quantifies the difference between 1.5-meter and 1.8-meter diameter dryers. The
paper provides equations for estimating the rimming speeds and collapsing speeds, using the same dimensionless
groups, and the associated drive power and torque.
ACKNOWLEDGEMENTS
The authors gratefully acknowledge the support of Kadant Johnson in conducting these studies and the technical
support of Jim Poulsen.
REFERENCES
1.
Concannon, M.D., “Condensate Effects on Torque and Horsepower in Paper Dryers,” Tappi 63(9): 69-72
(1980)
2.
White, R.E. and Higgins, T.W., “Effect of the Fluid Properties on Condensate Behavior,” Tappi 41 (2): 7176 (1958)
3.
Calkins, D.L., “A Comparison of Rotary & Stationary Siphon Performance in Paper Dryers,” Johnson
Corporation 1973.
4.
Derrick, R. P., "Drive Power Requirements for Pulp and Paper Machine Dryer Sections", 1978 Engineering
Conference Proceedings, Book II, Tappi Press, Atlanta, p. 381.
5.
Wedel, G. L. and Timm, G. L., “Drive Power and Torque in Papermachine Dryers”, TAPPI Technology
Summit 2002, Tappi Press, Atlanta.
Drive Power and Torque
in Papermachine Dryers
Greg Wedel – President
Kadant Johnson Inc.
1
Drying Process
Steam
Conde nsa te
Paper
Dryer Shell
2
Condensate Motion
Ponding
3
Cascading
Rimming
Dryer Bars
•
•
•
•
•
•
4
Axial bars
p
Held byy hoops
Increase turbulence
Increase heat transfer rate
Improve heat transfer uniformity
Affect drive power
Previous Studies
White, “Residual Condensate, Condensate Behavior, and Siphoning in
Paper Driers,” (1956)
White and
Whit
d Higgins,
Hi i
“Eff t off the
“Effect
th Fluid
Fl id Properties
P
ti
on Condensate
C d
t
Behavior,” (1958)
Calkins, “A Comparison of Rotary & Stationary Siphon Performance in
Calkins
Paper Dryers,” (1973)
Derrick, "Drive
Derrick
Drive Power Requirements for Pulp and Paper Machine
Dryer Sections", (1978)
Concannon, “Condensate
Concannon
Condensate Effects on Torque and Horsepower in Paper
Dryers,” (1980)
Wedel and Timm
Timm, “Drive
Drive Power and Torque in Papermachine Dryers”
Dryers ,
(2002)
5
Research Test Dryers
6
JOCO 4000 Test Dryer
7
Diameter
1.5 m
(5’)
Face
6.35 m
(250”)
Speed
1525 mpm
(5000 fpm)
Pressure
11 bar
(160 psi)
Condensing
49 kg/hr-m2
(10 lb/hr-ft2)
Syphon
Stationary or Rotating
Position
Plain shell or Syphon groove
JOCO 6000 Test Dryer
8
Diameter
1.8 m
(6’)
Face
8.81 m
(347”)
Speed
2000 mpm
(6600 fpm)
Pressure
11 bar
(160 psi)
Condensing
49 kg/hr-m2
(10 lb/hr-ft2)
Syphon
Stationary or Rotating
Position
Plain shell or Syphon groove
Testing Procedures
9
•
Meter in a fixed amount of water
•
Report volume as equivalent rimming depth
•
Increase speed in small increments
•
Measure drive torque at each increment
•
Video tape condensate behavior
•
Repeat for 5’ and for 6’ diameter dryers
•
Repeat with dryer bars
Condensate Behavior
10
Drive Power – 1.5 m diameter
((Without Dryer
y Bars))
3.0
12.7 mm rim layer
25
2.5
9.5 mm rim layer
Power, kW
W/m
6.4 mm rim layer
2.0
3.2 mm rim layer
1.6 mm rim layer
1.5
1.0
0.5
0.0
0
500
1000
Dryer Speed
Speed, m/min
11
1500
2000
Drive Power – 1.8 m diameter
((Without Dryer
y Bars))
3.0
12.7 mm rim layer
25
2.5
9 5 mm rim
9.5
i layer
l
Power, kW
W/m
6.4 mm rim layer
2.0
3.2 mm rim layer
1 6 mm rim
1.6
i layer
l
1.5
1.0
0.5
0.0
0
500
1000
Dryer Speed
Speed, m/min
12
1500
2000
Drive Power Observations
((Without Dryer
y Bars))
13
•
Drive p
power increases until rimming
g occurs
•
Drive power increases with rim depth
•
Drive power decreases at rimming speed
•
Drive power slowly increases above rimming
•
Rimming speed
d increases with
h rim depth
d
h
•
Drive power increases with dryer diameter
Drive Power – 1.5 m diameter
((With Dryer
y Bars))
3.0
12.7 mm rim layer
25
2.5
9.5 mm rim layer
Power, kW
W/m
6.4 mm rim layer
2.0
3.2 mm rim layer
1.6 mm rim layer
1.5
10
1.0
0.5
0.0
0
500
1000
Dryer
y Speed,
p , m/min
14
1500
2000
Drive Power – 1.8 m diameter
((With Dryer
y Bars))
3.0
12.7 mm rim layer
25
2.5
9 5 mm rim layer
9.5
Power, kW
W/m
6.4 mm rim layer
2.0
3.2 mm rim layer
1 6 mm rim layer
1.6
1.5
1.0
0.5
0.0
0
500
1000
Dryer Speed
Speed, m/min
15
1500
2000
Drive Power Observations
((With Dryer
y Bars))
Same general trends as without bars:
16
•
Drive power increases until rimming occurs
•
Drive power increases with rim depth
•
Drive power decreases at rimming speed
•
Drive power slowly increases above rimming
•
Rimming speed increases with rim depth
•
Drive power increases with dryer diameter
Drive Power Comparison
17
•
Ri
Rimming
i
speed
d iis reduced
d
d with
ihb
bars
•
Drive power for rimming decreases with bars
•
Drive power reduction is most significant
with large amounts of condensate
•
Drive power reduction was up to 60%
Drive Torque – 1.5 m diameter
((Without Dryer
y Bars))
250
12.7 mm rim layer
9.5 mm rim layer
200
Torque, N-m
m/m
6.4 mm rim layer
3.2 mm rim layer
150
1.6 mm rim layer
100
50
0
0
500
1000
D
Dryer
S
Speed,
d m/min
/ i
18
1500
2000
Drive Torque – 1.8 m diameter
((Without Dryer
y Bars))
250
12.7 mm rim layer
9.5 mm rim layer
200
Torque, N-m
m/m
6.4 mm rim layer
3.2 mm rim layer
150
1.6 mm rim layer
100
50
0
0
500
1000
Dryer Speed, m/min
19
1500
2000
Drive Torque Observations
(without dryer bars)
20
•
D i
Drive
torque increases
i
with
i h rim
i depth
d
h
•
Drive torque increases until rimming occurs
•
Drive torque decreases at the rimming speed
•
Above rimming, drive torque is constant
•
Drive torque increases with dryer diameter
Drive Torque – 1.8 m diameter
((With Dryer
y Bars))
250
12.7 mm rim layer
9.5 mm rim layer
200
Torque, N-n
n/m
6.4 mm rim layer
3.2 mm rim layer
150
1.6 mm rim
i layer
l
100
50
0
0
500
1000
Dryer Speed, m/min
21
1500
2000
Drive Torque Observations
((With Dryer
y Bars))
Same general trends as without bars:
22
•
Drive torque increases with rim depth
•
Drive torque
q
increases until rimming
g occurs
•
Drive torque decreases at the rimming speed
•
Above rimming,
rimming drive torque is nearly constant
•
Torque increases with dryer diameter
•
D
Dryer
bars
b
reduces
d
rimming
i
i
speed
d
•
Dryer bars have no effect on rimming torque
Drive Torque Comparison
23
•
Drive torque required to rim decreases
with dryer bars
•
Torque reduction is most significant with
l
larger
amounts off condensate
d
•
Drive torque reduction was up to 15%
•
Speed at which the maximum torque occurs
is reduced by bars
Drive Power – 1.5 m diameter
3.0
Peak Power
Increasing speed
Power, kkW/m
2.5
Decreasing speed
2.0
Collapsing Speed
1.5
Rimming Speed
1.0
0.5
0.0
0
200
400
600
800
1000
1200
1400
Dryer Speed, m/min
12.7 mm rim depth
24
Drive Power – 1.5 m diameter with bars
3.0
Increasing speed
2.5
Decreasing
g speed
p
Power, kW
W/m
2.0
Collapsing
Speed
Peak Power
1.5
Rimming Speed
1.0
0.5
0.0
0
200
400
600
800
1000
1200
1400
Dryer Speed,
Speed m/min
12.7 mm rim depth
25
Condensate Behavior – 1.5 m diameter
800
Rimming
Dryer Speed, m
D
m/min
600
T
Transition
iti
400
Cascading
200
speed to rim - calculated
speed at peak torque - calculated
speed for rim collapse - calculated
speed to rim - observed
speed at peak torque - observed
speed for rim collapse - observed
0
0
2
4
6
8
Ri Layer
Rim
L
Thickness
Thi k
- mm
26
10
12
14
Condensate Behavior – 1.8 m with bars
400
Rimming
Dryer Speed, m/min
D
300
T
Transition
iti
200
Cascading
100
speed to rim - calculated
speed at peak torque - calculated
speed for rim collapse - calculated
speed to rim - observed
speed at peak torque - observed
speed for rim collapse - observed
0
0
2
4
6
8
Ri Layer
Rim
L
Thickness
Thi k
- mm
27
10
12
14
Observations
• Condensate collapses at a much higher
speed than it rims, without dryer bars
• Dryer bars reduce the rimming speed to
the condensate collapsing speed
28
Peak Drive Power
4
1.5 meter diameter dryer, no bars observed
1.5 meter diameter dryer, no bars calculated
1.5 meter diameter dryer, with bars observed
1 5 meter diameter dryer
1.5
dryer, with bars calculated
1.8 meter diameter dryer, no bars observed
1.8 meter diameter dryer, no bars calculated
1.8 meter diameter dryer, with bars observed
1 8 meter diameter dryer
1.8
dryer, with bars calculated
Power, kW//m
3
No bars
2
1
Dryer bars
0
0
2
4
6
8
Ri Layer
Rim
L
Thickness,
Thi k
mm
29
10
12
14
Peak Drive Torque
400
1.5 meter diameter dryer, no bars observed
1.5 meter diameter dryer, no bars calculated
1.5 meter diameter dryer, with bars observed
1.5 meter diameter dryer, with bars calculated
1.8 meter diameter dryer, no bars observed
1.8 meter diameter dryer, no bars calculated
1.8 meter diameter dryer, with bars observed
1.8 meter diameter dryer, with bars calculated
Torque, N-m/m
300
No bars
200
100
Dryer bars
0
0
2
4
6
8
Ri Layer
Rim
L
Thickness,
Thi k
mm
30
10
12
14
Observations
Drive Power Comparison
p
31
•
Peak drive power is much lower with bars
•
Peak drive toque is slightly higher with bars
Condensate Behavior
32
Correlation Equations (with and without bars)
Rimming Speed
V = 12 . 4 (δ g )
0 .5
V = 2 .9 (δ g )
(R / δ )
0 .5
(R / δ )
0 . 18
0 .362
(δ g / ν )
3
2
(δ g / ν )
3
2
0 . 013
0 .013
Collapsing Speed
C = 2 . 0 ( δ g ) 0 . 5 ( R / δ ) 0 . 452 ( δ 3 g / ν 2 ) 0 . 013
C = 7 . 1 (δ g ) 0 .5 ( R / δ ) 0 .107 (δ 3 g / ν 2 ) 0 .013
33
Drive Power (with and without bars)
P = Pp ( S / V )
2
(below rimming)
Pp = γ δ R (δ g ) ( R / δ )
0.5
P = (0.4 × 10 −6 ) S 2
0.41
(δ g /ν )
3
2 0.013
/ 1098
(above rimming)
(below rimming)
P = Pp (S /V )2
Pp = γ δ R (δg )0.5 (R / δ )0.463(δ 2 g /ν 2 )0.013 / 2780
P = (0.5 ×10−3 ) S
34
(above rimming)
Drive Power Predictions
((Without Dryer
y Bars))
1.8
1.6
Power, kW//m
1.4
1.2
1.0
0.8
0.6
0.4
Power - observed
0.2
Power - calculated
0.0
0
500
1000
1500
Dryer Speed, m/min
35
2000
2500
Drive Torque Predictions
((Without Dryer
y Bars))
180.0
Torque - observed
160.0
Torque - calculated
Torque, N-m
m/m
140.0
120.0
100.0
80.0
60.0
40.0
20.0
0.0
0
500
1000
1500
Dryer
y Speed,
p , m/min
36
2000
2500
Drive Power Predictions
((With Dryer
y Bars))
0.9
0.8
Power, kW//m
0.7
0.6
0.5
0.4
0.3
0.2
Power - observed
0.1
Power - calculated
0.0
0
200
400
600
800
1000
Dryer Speed, m/min
37
1200
1400
1600
Dryer Torque Predictions
((With Dryer
y Bars))
140.0
Torque
q - observed
120 0
120.0
Torque - calculated
Torque, N-m
m/m
100.0
80.0
60.0
40.0
20.0
0.0
0
200
400
600
800
1000
Dryer Speed,
Speed m/min
38
1200
1400
1600
Observations
Correlations predict:
39
•
Rimming speed
•
Non-rimming
Non
rimming power
•
Non-rimming torque
•
Rimming power
•
Rimming torque
General Summary
Increased rim depth will:
•
Increase speed required to rim
•
Increase drive power required to rim
•
Increase drive torque required to rim
Dryer
ye bars
ba s will:
40
•
Reduce the speed required to rim
•
Reduce the drive power required to rim
•
Reduce the torque required to rim
Drive Power and Torque in Papermachine Dryers
41
Drive Power and Torque
in Papermachine Dryers
42