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Positioner Selection and Motor Sizing...Positioner Selection Criteria Positioner Selection and motor...
Transcript of Positioner Selection and Motor Sizing...Positioner Selection Criteria Positioner Selection and motor...
Positioner Selection and Motor Sizing
Jim WileyProduct Manager
Parker Hannifin
Overview
Positioner Selection
Motor & Drive Sizing
Positioner Selection Criteria
Precision
Loading
Environment
Geometry
Motion
Positioner Selection Criteria
Positioner Selection and motor sizing is not a strictly linear process.
One set of criteria might restrict another, for example travel distance v. precision or load v. motion profile.
Selection often requires compromise and reassessment of needs based on budget, size constraints and other goals.
In many cases there is more than one right answer
Precision
Loading
EnvironmentGeometry
Motion
Application Categories
Making
β’ Transform
β’ Welding, Cutting, Etching, Dispensing, Bending
Moving
β’ Transfer
β’ Pick & Place, Storage & retrieval, palletize, Shuttle
Measuring
β’ Test
β’ Inspection, Vision, Gauging, Sampling
Positioner Selection : Precision
Accuracy is βmore expensiveβ than repeatability so be sure to understand the difference and machine requirements
Making
Moving
Measuring
Precision
Accuracy
Repeatability
Accuracy
Positioner Selection : Geometry
Rod Style
β’ Electric Cylinder
β’ Rodded Actuator
β’ PistonRodless Actuator
β’ Electric Actuator
β’ Linear Actuator
Linear Positioner
β’ Linear Table
β’ Linear Stage
Positioner Selection : Geometry
Rod StyleDefining characteristics:
Non-constant support geometry
Packaged drivetrain, guidance and moving rod
Similar functionality to pneumatic and hydraulic
cylinders
Applications:
Push/pull
Push to force
Pressing
Forming
Clamping
Vertical axis in gantry
Good for-
High thrust force applications
Vertical applications
Fluid power conversion
Reach in and retract applications
Positioner Selection : Geometry
Rodless Actuator
Defining characteristics:
Constant support geometry
Packaged drivetrain, guidance and moving
carriage assembly
Single linear guide
Applications:
Pick and place
Push to force
Indexing
Cutting/feeding
Material Handling
Good for-
Low Cost
Flexibility- drive trains/guides
Scalability- multiple frame sizes
Long stroke
Moderate payloads
Industrial applications
Positioner Selection : Geometry
Linear Positioner
Defining characteristics:
Constant support geometry
Packaged drivetrain, guidance and moving
carriage assembly
Dual linear guides
Applications:
High precision positioning
Dynamic control
Multi-axis
Scanning
Metrology
Electronics mfg
Good for-
Precision positioning
High moment loading
Multi-Axis Stacking
Straightness/flatness
Positioner Selection : Travel
Determine Overall Travel Distance/StrokeDrive TrainGuidance SystemMounting Considerations
Review how the overall length of the positioner impacts the machine constraints
Positioner Selection : Precision
Positioner Specifications will typically call out a repeatability as a +/-value.
Positional Accuracy, straightness is generally travel length dependent.
Positioner Selection : Precision
Straightness and Flatness are generally travel length dependent.
Positioner Selection : Precision
Errors can occur in 6 different ways in a linear positioning device:
Guidance system, drive train, machined surfaces, assembly techniques all contribute the accuracy specification.
XZ Y
YAW
PITCH
Positioner Selection : Motion Profile
Review Motion profile requirements to determine maximum speed and acceleration
Motion
Positioner Selection : Motion Profile
Trapezoidal Move Profile: π½ππππππππ΄ππππππ =1.5βπ·
π‘
π¨ππππππππππππ΄ππππππ =4.5βπ·
π‘2
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Positioner Selection : Motion Profile
Positioner Specifications will typically rate a maximum allowable velocity and acceleration based on the drive train and guidance system limits.
Maximum velocity will vary based on overall travel distance and in the case of ballscrew, the lead (or pitch of the screw.
Load Selection Criteria
Select Positioner based on
Normal Load capacity
Moment load capacity
Axial load capacity
Load Selection Criteria
Consider
Mounting Orientation
Load Center of gravity
Axial load capacity
Load Selection Criteria
Moment Load Capacity
Load Selection Criteria
Load Selection Criteria
Load Selection Criteria
Maximum Load Rating
Load/Life Charts based in cumulative travel distance
Load Selection Criteria
Environmental
Environmental conditions may lead to additional design considerations
Dust/Dirt/Debris>>>> Sealing/Bellows
Clean room/Vacuum/Explosion>>>Special preparation
Overview
Positioner Selection
Motor & Drive Sizing
Motor Sizing
Speed
Peak Torque
AmplifierInertia
Continuous Torque
Motor Sizing
Convert required linear speed to rotational speed
Simple rotational velocity equation for a screw device:
π =π β π
πΏ
π = rotational velocity required (RPM, RPS)
π = linear velocity (in/s, m/s)
π = any gear reduction ratio
πΏ = Lead of the screw (mm, in)
Example: π = 300 ππ/secπΏ = 12 mm screw
π =300 ππ/π
12πππππ£
= 25RPS
or 1500 RPM
Motor Sizing
Convert required linear acceleration to rotational acceleration
Simple rotational acceleration equation for a screw device:
πΌ =π΄ β π
πΏ
πΌ = rotational acceleration required (RPS)
π΄ = linear acceleration (in/s2, m/s2)
π = any gear reduction ratio
πΏ = Lead of the screw (mm, in)
Example: π΄ = 3 m/sec2
πΏ = 12 mm screw
πΌ =3 m/sec2
12πππππ£
= 250 πππ£/π ππ2
Ξ± = 2π β πππ/ rev Γ250 πππ£/π ππ2
Ξ± = 1570 πππ/π ππ2
Motor Sizing
Peak Torque
The total torque required from the motor to move itself and the load
π»π = π»π +π»π + π»πππππ
ππ‘ = π‘ππ‘ππ ππππππ = πππππππππ‘πππ π‘ππππ’πππ = πππππ‘πππ π‘ππππ’π ππ π βπ
πππ‘βππ= π‘ππππ’π ππππ ππππ£ππ‘π¦, ππππππππ , ππ’π β/ππ’ππ ππππππ ππ = ππππ£ππ‘π¦ π‘ππππ’π ππ π βπ
Motor Sizing
Acceleration Torque
ππ = π½π‘ππ‘ππ Γ πΌ
π½π‘ππ‘ππ = π½π + π½πΏ + π½π
ππ = acceleration torque
Ξ± = angular acceleration, rad/sec2
π½π = inertia of motor
π½πΏ = reflected inertia of load thru mechanics
π½π = inertia of positioner mechanics
πΌ = angular acceleration, rad/sec2
Motor Sizing : Inertia
Determine the reflected inertia of the load back to the motor
For ballscrew:
π½πΏ =πππππ β (πΏ
2π)2
JL = reflected inertia of loadthru mechanicsπππππ= payload in kgL= Lead of screw (mm, in)
Example: πππππ = 50πππΏ = 12ππ/πππ£
π½πΏ = 50ππ β (0.012π
2π)2
π½πΏ =0.00018 ππ β π2
Motor Sizing : Torque
Use reflected inertia to approximate acceleration torque
ππ = (π½πΏ + π½π) Γ πΌ
Example: πππππ = 50πππΏ = 12ππ/πππ£
π½πΏ = 50ππ β (0.012π
2π)2
π½πΏ =0.00018 ππ β π2
Ξ± = 1570 πππ/π ππ2
π½πΏ = 0.000182 ππ β π2
π½π = 0.0000042 ππ β π2
ππ = 0.000186 ππ β π2 Γ1570 πππ/π ππ2
ππ = 0.34ππ
π½π
Motor Sizing : Torque
Total Torque
π»π = π»π +π»π + π»πππππ
ππ‘ = 0.34 + 0.2 = 0.54ππ
Motor Sizing : Torque
Peak Torque Required = 0.55Nm @ 1500rpm
Motor Sizing : Torque
Peak Torque Required = 0.55Nm @ 1500rpm
Peak Versus Continuous
Determining and RMS or effective torque is pertinent for determining a number of itemsAppropriately sizing a system (actuator, motor, and drive)
Accurately modeling the life of a system
Be sure to include dwells or periods of rest
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Calculating RMS Torque
Once forces are modeled by unit of time the following equation can then be applied:
πππππ’ππ ππ = π=1π=πππ
2 β π‘π
π=1π=π π‘π
Where:
T = is the Torque require per time segment (ti)
ti = is the time segment a force is seen, include dwells if being used for motor sizing
n = the total number of segments in a motion profile.
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Calculating RMS Torque
πππππ’ππ ππ = π=1π=πππ
2 β π‘π
π=1π=π π‘π
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t T T^2 T^2*t0.15 0.55 0.3025 0.166375
1 0.2 0.04 0.0080.15 0.55 0.3025 0.166375
1 0.2 0.04 0.0080.15 0.55 0.3025 0.166375
tsum 2.45 0.515125 0.2102550.458536
Motor Sizing : Torque
Peak Torque Required = 0.55Nm @ 1500rpm
Continuous Torque Required = 0.45Nm @ 1500rpm
Motor Sizing : Inertia Ratio
reflected inertia of the load compared to motor inertia
π½πΏ =πππππ β (πΏ
2π)2
π½πΏ =0.00018 ππ β π2
π½π =0.000009 ππ β π2
π½πΏ/π½π= 19.9
Motor Sizing : Inertia Ratio
reflected inertia of the load compared to motor inertia
π½πΏ/π½π= 10.5
π±π³/π±π= 7.8
Motor Sizing
Screw Lead Motor Speed Inertia Ratio Motor Torque Torque Margin
5 3600 1.34 0.12 10.9
12 1500 7.70 0.29 4.5
16 1125 13.68 0.38 3.4
25 720 33.40 0.60 2.2
Linear Speed 300mm/sec
Acceleration 3000mm/sec2
Load 50kg
Motor Inertia 2.37 e-5 kg-m^2
Motor Torque 1.3Nm
Motor Sizing
Motor Sizing
Convert required linear speed to rotational speed
Rotational speed for belt and pulley :
π =π β π
2ππ
V = required linear velocity (in/s, m/s)
R = any additional gear reduction
r = radius of the drive pulley
Example: V = 800 mm/secr = 45 mm pulley
π =800 ππ/π
2π β 45 ππ= 2.83RPS
or 170 RPM
Example: V = 800 mm/secr = 45 mm pulley R=10: 1 gear
π =800
πππ β 10
2π β 45 ππ= 28.3RPS
or 1700 RPM
Motor Sizing
Gear ratioMotor Speed, rpm Inertia Ratio Motor Torque Torque Margin
1 170 2136 :1 3.38 0.4
5 849 85:1 0.68 1.9
10 1698 21 :1 0.34 3.9
20 3395 5:1 0.17 7.7
Linear Speed 800mm/sec
Acceleration 3000mm/sec2
Load 25kg
Motor Inertia 2.37 e-5kg-m^2
Motor Torque 1.3Nm
Motor Sizing
Speed
Peak Torque
AmplifierInertia
Continuous Torque
Jim WileyProduct Manager
Parker Hannifin Corporation
Electromechanical & Drives
5500 Business Park Drive
Rohnert Park, CA 94928
Telephone: 707-584-2541
Email: [email protected]
www.parker.com/emn