China Plf120 Ratio 20 Planetary Gearbox with high quality

Product Description

1. PLF collection precision planetary gear speed reducer Design: PLF40, PLF60, PLF90, PLF120, PLF160, PLF200
2. The pace ratio: 3, 4, 5, 7, 9, ten, 15, 20, 25, thirty, 35, forty, 50, sixty four, 70, eighty, a hundred, one hundred fifty, two hundred, 250, 350, 400, five hundred, seven-hundred, a thousand
3. Stages: Three
Efficiency and functions:
1. Planetary equipment transmission interface making use of doesn’t incorporate total needle needle bearing, and enhance the make contact with location to boost structural rigidity and output torque
two. PLFseries precision planetary gear reducer, with higher precision, high rigidity, substantial load, higher performance, high pace ratio, large life, low inertia, minimal vibration, reduced noise, low temperature rising, lovely appearance, composition, light-weight fat, effortless installation, accurate positioning, etc, and is suitable for AC servo motor, DC servo motor, stepper motor, hydraulic motor of progress and gradual down transmission

Type PLF-40 PLF-60 PLF-ninety PLF-120 PLF-one hundred sixty PLF-two hundred Ratio Stages
T2N
Rated output torque
(Nm)
ten 28 one hundred twenty 220 480 1230 3 1
fifteen forty eight one hundred fifty 270 590 1450 four
fifteen forty eight one hundred fifty 270 590 1450 5
nine 39 one hundred ten 215 470 1130 7
seven 19 58 98 260 720 10
ten 28 120 220 480 1230 nine two
15 forty eight one hundred fifty 270 590 1450 15
15 48 150 270 590 1450 twenty
fifteen forty eight one hundred fifty 270 590 1450 twenty five
fifteen 48 150 270 590 1450 thirty
fifteen forty eight one hundred fifty 270 590 1450 35
15 forty eight one hundred fifty 270 590 1450 forty
fifteen 48 150 270 590 1450 fifty
9 39 one hundred ten 215 470 1130 70
seven 19 58 98 260 720 one hundred
fifteen 48 150 270 590 1450 64 3
15 forty eight a hundred and fifty 270 590 1450 80
fifteen forty eight a hundred and fifty 270 590 1450 100
15 forty eight one hundred fifty 270 590 1450 a hundred and fifty
15 forty eight one hundred fifty 270 590 1450 200
fifteen forty eight a hundred and fifty 270 590 1450 250
15 48 one hundred fifty 270 590 1450 350
fifteen 48 a hundred and fifty 270 590 1450 400
fifteen 48 a hundred and fifty 270 590 1450 five hundred
nine 39 one hundred ten 215 470 1130 seven hundred
seven 19 58 ninety eight 260 720 1000
emergency end torque T2not=2T2N
Rotational inertia
(kgm2)
.031 .0135 .seventy seven two.63 twelve.14 15.6 three 1
.571 .093 .fifty two one.79 seven.seventy eight sixteen.three four
.019 .078 .forty five one.53 6.07 15.4 5
.017 .065 .39 one.32 4.63 sixteen.1 7
.016 .065 .39 1.32 4.sixty three 15.two ten
.03 .131 .74 two.62 twelve.14 fifteen.nine 9 two
.571 .077 .seventy one 2.53 12.35 fifteen 15
.019 .075 .44 1.5 six.sixty five 15.seven twenty
.019 .075 .44 one.49 five.81 15.three twenty five
.017 .064 .39 1.3 six.36 15.2 30
.016 .064 .39 one.3 5.28 sixteen.1 35
.016 .064 .39 one.three 5.28 fifteen.two forty
.016 .064 .39 one.3 4.5 15.2 fifty
.016 .064 .39 one.3 4.five fifteen.2 70
.016 .058 .31 1.twelve 3.fifty three fifteen.two 100
.019 .075 .5 one.5 7.5 fifteen.4 80 three
.019 .075 .forty four 1.forty nine seven.4 15.4 one hundred
.016 .064 .39 1.three six.five 15.2 one hundred fifty
.016 .064 .39 one.three 6.two fifteen.2 two hundred
.016 .064 .39 one.3 five.7 15.2 250
.016 .064 .39 1.three five.four fifteen.two 350
.016 .064 .39 one.three five.four fifteen.two 400
.016 .064 .39 1.three five.2 fifteen.two 500
.016 .064 .39 1.three five.two 15.two seven hundred
.016 .064 .39 1.3 5.two 15.2 a thousand
backslash
(arcmin)
lowered <5 <3 <3 <3 <5 <10   1
normal <10 <8 <8 <8 <10 <15  
decreased <8 <5 <5 <5 <8 <15   2
standard <12 <10 <10 <10 <10 <18  
reduced <10 <8 <8 <8 <10 <18   3
regular <15 <12 <12 <12 <15 <22  
torsional rigidity
(Nm/arcmin)
.7 1.8 four.four 9.2 26.7 66.7  
noise dB(A) fifty five fifty eight sixty sixty five 70 75  
Max.input speed 10000 8000 6000 6000 5000 3500 1-min
Rated input speed 4500 4000 4000 3500 2000 1500 1-min
Max.Radialforce(N) 185 265 four hundred 1240 3700 6700 Stages
Max.Axialforce(N) one hundred fifty two hundred 420 1000 3500 3800
Full-load effectiveness(%) 96 1
94 2
90 3
 service lifestyle (H) 20000  
Weight (Kg) .five 1 three 6.2 19 forty two 1
.eight 1.five 4.2 eight 24 fifty 2
one.1 one.eight 4.8 nine.eight 29 58 3

US $200-2,000
/ unit
|
1 unit

(Min. Order)

###

Application: Machinery
Function: Speed Changing, Speed Reduction
Layout: Cycloidal
Hardness: Hardened Tooth Surface
Installation: Vertical Type
Step: Double-Step

###

Customization:

###

Type PLF-40 PLF-60 PLF-90 PLF-120 PLF-160 PLF-200 Ratio Stages
T2N
Rated output torque
(Nm)
10 28 120 220 480 1230 3 1
15 48 150 270 590 1450 4
15 48 150 270 590 1450 5
9 39 110 215 470 1130 7
7 19 58 98 260 720 10
10 28 120 220 480 1230 9 2
15 48 150 270 590 1450 15
15 48 150 270 590 1450 20
15 48 150 270 590 1450 25
15 48 150 270 590 1450 30
15 48 150 270 590 1450 35
15 48 150 270 590 1450 40
15 48 150 270 590 1450 50
9 39 110 215 470 1130 70
7 19 58 98 260 720 100
15 48 150 270 590 1450 64 3
15 48 150 270 590 1450 80
15 48 150 270 590 1450 100
15 48 150 270 590 1450 150
15 48 150 270 590 1450 200
15 48 150 270 590 1450 250
15 48 150 270 590 1450 350
15 48 150 270 590 1450 400
15 48 150 270 590 1450 500
9 39 110 215 470 1130 700
7 19 58 98 260 720 1000
emergency stop torque T2not=2T2N
Rotational inertia
(kgm2)
0.031 0.0135 0.77 2.63 12.14 15.6 3 1
0.022 0.093 0.52 1.79 7.78 16.3 4
0.019 0.078 0.45 1.53 6.07 15.4 5
0.017 0.065 0.39 1.32 4.63 16.1 7
0.016 0.065 0.39 1.32 4.63 15.2 10
0.03 0.131 0.74 2.62 12.14 15.9 9 2
0.023 0.077 0.71 2.53 12.35 15 15
0.019 0.075 0.44 1.5 6.65 15.7 20
0.019 0.075 0.44 1.49 5.81 15.3 25
0.017 0.064 0.39 1.3 6.36 15.2 30
0.016 0.064 0.39 1.3 5.28 16.1 35
0.016 0.064 0.39 1.3 5.28 15.2 40
0.016 0.064 0.39 1.3 4.5 15.2 50
0.016 0.064 0.39 1.3 4.5 15.2 70
0.016 0.058 0.31 1.12 3.53 15.2 100
0.019 0.075 0.5 1.5 7.5 15.4 80 3
0.019 0.075 0.44 1.49 7.4 15.4 100
0.016 0.064 0.39 1.3 6.5 15.2 150
0.016 0.064 0.39 1.3 6.2 15.2 200
0.016 0.064 0.39 1.3 5.7 15.2 250
0.016 0.064 0.39 1.3 5.4 15.2 350
0.016 0.064 0.39 1.3 5.4 15.2 400
0.016 0.064 0.39 1.3 5.2 15.2 500
0.016 0.064 0.39 1.3 5.2 15.2 700
0.016 0.064 0.39 1.3 5.2 15.2 1000
backslash
(arcmin)
reduced <5 <3 <3 <3 <5 <10   1
standard <10 <8 <8 <8 <10 <15  
reduced <8 <5 <5 <5 <8 <15   2
standard <12 <10 <10 <10 <10 <18  
reduced <10 <8 <8 <8 <10 <18   3
standard <15 <12 <12 <12 <15 <22  
torsional rigidity
(Nm/arcmin)
0.7 1.8 4.4 9.2 26.7 66.7  
noise dB(A) 55 58 60 65 70 75  
Max.input speed 10000 8000 6000 6000 5000 3500 1-min
Rated input speed 4500 4000 4000 3500 2000 1500 1-min
Max.Radialforce(N) 185 265 400 1240 3700 6700 Stages
Max.Axialforce(N) 150 200 420 1000 3500 3800
Full-load efficiency(%) 96 1
94 2
90 3
 service life (H) 20000  
Weight (Kg) 0.5 1 3 6.2 19 42 1
0.8 1.5 4.2 8 24 50 2
1.1 1.8 4.8 9.8 29 58 3
US $200-2,000
/ unit
|
1 unit

(Min. Order)

###

Application: Machinery
Function: Speed Changing, Speed Reduction
Layout: Cycloidal
Hardness: Hardened Tooth Surface
Installation: Vertical Type
Step: Double-Step

###

Customization:

###

Type PLF-40 PLF-60 PLF-90 PLF-120 PLF-160 PLF-200 Ratio Stages
T2N
Rated output torque
(Nm)
10 28 120 220 480 1230 3 1
15 48 150 270 590 1450 4
15 48 150 270 590 1450 5
9 39 110 215 470 1130 7
7 19 58 98 260 720 10
10 28 120 220 480 1230 9 2
15 48 150 270 590 1450 15
15 48 150 270 590 1450 20
15 48 150 270 590 1450 25
15 48 150 270 590 1450 30
15 48 150 270 590 1450 35
15 48 150 270 590 1450 40
15 48 150 270 590 1450 50
9 39 110 215 470 1130 70
7 19 58 98 260 720 100
15 48 150 270 590 1450 64 3
15 48 150 270 590 1450 80
15 48 150 270 590 1450 100
15 48 150 270 590 1450 150
15 48 150 270 590 1450 200
15 48 150 270 590 1450 250
15 48 150 270 590 1450 350
15 48 150 270 590 1450 400
15 48 150 270 590 1450 500
9 39 110 215 470 1130 700
7 19 58 98 260 720 1000
emergency stop torque T2not=2T2N
Rotational inertia
(kgm2)
0.031 0.0135 0.77 2.63 12.14 15.6 3 1
0.022 0.093 0.52 1.79 7.78 16.3 4
0.019 0.078 0.45 1.53 6.07 15.4 5
0.017 0.065 0.39 1.32 4.63 16.1 7
0.016 0.065 0.39 1.32 4.63 15.2 10
0.03 0.131 0.74 2.62 12.14 15.9 9 2
0.023 0.077 0.71 2.53 12.35 15 15
0.019 0.075 0.44 1.5 6.65 15.7 20
0.019 0.075 0.44 1.49 5.81 15.3 25
0.017 0.064 0.39 1.3 6.36 15.2 30
0.016 0.064 0.39 1.3 5.28 16.1 35
0.016 0.064 0.39 1.3 5.28 15.2 40
0.016 0.064 0.39 1.3 4.5 15.2 50
0.016 0.064 0.39 1.3 4.5 15.2 70
0.016 0.058 0.31 1.12 3.53 15.2 100
0.019 0.075 0.5 1.5 7.5 15.4 80 3
0.019 0.075 0.44 1.49 7.4 15.4 100
0.016 0.064 0.39 1.3 6.5 15.2 150
0.016 0.064 0.39 1.3 6.2 15.2 200
0.016 0.064 0.39 1.3 5.7 15.2 250
0.016 0.064 0.39 1.3 5.4 15.2 350
0.016 0.064 0.39 1.3 5.4 15.2 400
0.016 0.064 0.39 1.3 5.2 15.2 500
0.016 0.064 0.39 1.3 5.2 15.2 700
0.016 0.064 0.39 1.3 5.2 15.2 1000
backslash
(arcmin)
reduced <5 <3 <3 <3 <5 <10   1
standard <10 <8 <8 <8 <10 <15  
reduced <8 <5 <5 <5 <8 <15   2
standard <12 <10 <10 <10 <10 <18  
reduced <10 <8 <8 <8 <10 <18   3
standard <15 <12 <12 <12 <15 <22  
torsional rigidity
(Nm/arcmin)
0.7 1.8 4.4 9.2 26.7 66.7  
noise dB(A) 55 58 60 65 70 75  
Max.input speed 10000 8000 6000 6000 5000 3500 1-min
Rated input speed 4500 4000 4000 3500 2000 1500 1-min
Max.Radialforce(N) 185 265 400 1240 3700 6700 Stages
Max.Axialforce(N) 150 200 420 1000 3500 3800
Full-load efficiency(%) 96 1
94 2
90 3
 service life (H) 20000  
Weight (Kg) 0.5 1 3 6.2 19 42 1
0.8 1.5 4.2 8 24 50 2
1.1 1.8 4.8 9.8 29 58 3

How to Calculate Transmission Ratio for a Cycloidal Gearbox

Using a cycloidal gearbox can be very useful in a wide variety of situations. However, it’s important to understand how to use it properly before implementing it. This article discusses the benefits of using a cycloidal gearbox, how to calculate the transmission ratio, and how to determine the effects of dynamic and inertial forces on the gearbox.helical gearbox

Dynamic and inertial effects

Various studies have been done to study the dynamic and inertial effects of cycloidal gearboxes. These studies have been performed using numerical, analytical and experimental methods. Depending on the nature of the load and its distribution along the gear, a variety of models have been developed. These models use finite element method to determine accurate contact stresses. Some of these models have been developed to address the nonlinear elasticity of contacts.
Inertial imbalance in a cycloidal gearbox causes vibration and can affect the efficiency of the device. This can increase mechanical losses and increase wear and tear. The efficiency of the device also depends on the torque applied to the cycloidal disk. The effectiveness of the device increases as the load increases. Similarly, the nonlinear contact dynamics are also associated with an increase in efficiency.
A new model of a cycloidal reducer has been developed to predict the effects of several operational conditions. The model is based on rigid body dynamics and uses a non-linear stiffness coefficient. The model has been validated through numerical and analytical methods. The model offers drastic reduction in computational costs. The model allows for a quick analysis of several operational conditions.
The main contribution of the paper is the investigation of the load distribution on the cycloidal disc. The study of this aspect is important because it allows for an analysis of the rotating parts and stresses. It also provides an indication of which gear profiles are best suited for optimizing torque transmission. The study has been conducted with a variety of cycloidal gearboxes and is useful in determining the performance of different types of cycloidal gearboxes.
To study the load distribution on the cycloidal disc, the authors investigated the relationship between contact force, cycloidal gearboxes and different gear profiles. They found that the non-linear contact dynamics have a large impact on the efficiency of a cycloidal gearbox. The cycloidal gearbox is an ideal solution for applications that involve highly dynamic servos. It can also be used in machine tool applications and food processing industries.
The study found that there are three common design principles of cycloidal reducers. These are the contact force distribution, the speed reduction and the trochoidal profile of the cycloidal disc. The trochoidal profile has to be defined carefully to ensure correct mating of the rotating parts. The trochoidal profile provides an indication of which gear profiles are best for optimizing torque transmission. The contact force distribution can be improved by refining the mesh along the disc’s width.
As the input speed increases, the efficiency of the reducer increases. This is because contact forces are constantly changing in magnitude and orientation. A cycloidal reducer with a one tooth difference can reduce input speed by up to 87:1 in a single stage. It also has the ability to handle high-cycle moves without backlash.helical gearbox

Transmission ratio calculation

Getting the correct transmission ratio calculation for a cycloidal gearbox requires a good understanding of what a gearbox is, as well as the product that it is being used for. The correct ratio is calculated by dividing the output speed of the output gear by the input speed of the input gear. This is usually accomplished by using a stopwatch. In some cases, a catalog or product specification may be required. The correct ratio is determined by a combination of factors, such as the amount of torque applied to the mechanism, as well as the size of the gears involved.
A cycloidal gear is a type of gear tooth profile that can be represented using a spline. It is also possible to model a gear with a cycloidal profile by using a spline to connect points against the beginning of a coordinate system. This is important in the design and functionality of a gear.
There are many different gears used in machines and devices. These include the herringbone gear, the helical gear and the spiral bevel gear. The best transmission ratios are typically obtained with a cycloidal gearbox. In addition to ensuring the accuracy of positioning, a cycloidal gearbox provides excellent backlash. Cycloid gears have a high degree of mechanical efficiency, low friction, and minimal moment of inertia.
A cycloidal gearbox is often referred to as a planetary gearbox, though it is technically a single-stage gearbox. In addition to having a ring gear, the gearbox has an eccentric bearing that drives the cycloidal disc in an eccentric rotation. This makes the cycloidal gearbox a good choice for high gear ratios in compact designs.
The cycloid disc is the key element of a cycloidal gearbox. The cycloid disc has n=9 lobes, and each lobe of the disc moves by a lobe for every revolution of the drive shaft. The cycloid disc is then geared to a stationary ring gear. The cycloidal disc’s lobes act like teeth on the stationary ring gear.
There are many different gears that are classified by the profile of the gear teeth. The most common gears are the involute and helical gears. Most motion control gears include spur designs. However, there are many other types of gears that are used in various applications. The cycloidal gear is one of the more complicated gears to design. The cycloid disc’s outline can be represented using markers or smooth lines, though a scatter chart will also do.
The cycloid disc’s lobes rotate on a reference pitch circle of pins. These pins rotate 40 deg during the eccentric rotation of the drive shaft. The pins rotate around the disc to achieve a steady rotation of the output shaft.
The cycloid disc’s other obvious, and possibly more important, feature is the’magic’ number of pins. This is the number of pins that protrude through the face of the disc. The disc has holes that are larger than the pins. This allows the pins to protrude through the disc and attach to the output shaft.helical gearbox

Application

Whether you’re building a robot drive or you’re simply looking for a gearbox to reduce the speed of your vehicle, a cycloidal gearbox is a great way to achieve a high reduction ratio. Cycloidal gearboxes are a low-friction, lightweight design that has an extremely stable transmission. They are suitable for industrial robots and can be used in many applications, including positioning robots.
Cycloidal gearboxes reduce speed by using eccentric motion. The eccentric motion enables the entire internal gear to rotate in wobbly cycloidal motion, which is then translated back into circular rotation. This eliminates the need for stacking gear stages. Cycloidal gearboxes also have less friction, higher strength, and greater durability than conventional gearboxes.
The cycloidal gearbox is also used in a number of applications, including marine propulsion systems, and robot drives. Cycloidal gearboxes reduce vibration by using offset gearing to cancel out vibrations.
Cycloidal gears have lower friction, higher strength, and better torsional stiffness than involute gears. They also have a reduced Hertzian contact stress, making them better than involute gears for use with shock loads. They also have a smaller size and weight than conventional gearboxes, and they have a higher reduction ratio than involute gears.
Cycloidal gears are typically used to reduce the speed of motors, but they also offer a number of other advantages. Cycloidal gearboxes have a smaller footprint than other gearboxes, allowing them to fit into confined spaces. They also have low backlash, allowing for precise movement. Cycloidal gears have a higher efficiency, resulting in lower power requirements and lower wear.
The cycloidal disc is one of the most important components of the gearbox. Cycloidal discs are normally designed with a short cycloid, which minimizes the eccentricity of the disc. They are also designed with a shortened flank, resulting in better strength and less stress concentration. Cycloidal discs are typically geared to a stationary ring gear. The cycloid is designed to roll around the stationary ring pins, which push against the circular holes in the disc. Cycloidal gearboxes typically employ two degrees of shift.
Cycloidal drives are ideal for heavy load applications. They also have high torsional stiffness, which makes them highly resistant to shock loads. Cycloidal drives also offer a high reduction ratio, which can be achieved without the need for a large input shaft. They are also compact and have a high service life.
The output shaft of a cycloidal gearbox always has two degrees of shifting, which ensures that the input and output shafts always rotate at a different speed. The output shaft would be a pin casing around the drive disks, which would also allow for easy maintenance.
Cycloidal gearboxes are also very compact and lightweight, so they are ideal for use in industrial robots. The cycloidal gearbox reducer is the most stable, low-vibration reducer in industrial robots, and it has a wide transmission ratio range.
China Plf120 Ratio 20 Planetary Gearbox     with high quality China Plf120 Ratio 20 Planetary Gearbox     with high quality
editor by czh 2022-12-16

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