Robotic motions rely on electrical, pneumatic, or hydraulic power sources and digital controllers to coordinate movements. There are three main components of robots: drives that provide power, controllers that determine how power is used to move actuators and carry tools, and effectors or tools. Controllers coordinate robot movements and receive input from sensors. Robotic motions are initiated by programs stored in the controller's memory.
basic understanding of the servo motors
1-components
2-how it works
3-advantages and disadvantages of the servo motor
4-what size of the servo motor to select
basic understanding of the servo motors
1-components
2-how it works
3-advantages and disadvantages of the servo motor
4-what size of the servo motor to select
Stepper Motor Types, Advantages And Applicationselprocus
A stepper motor is an electromechanical device which converts electrical pulses into discrete mechanical movements. The shaft or spindle of a stepper motor rotates in discrete step increments when electrical command pulses are
applied to it in the proper sequence. The motors rotation has several direct relationships to these applied input pulses. The sequence of the applied pulses is directly related to the direction of motor shafts rotation. The speed of the
motor shafts rotation is directly related to the frequency of the input pulses and the length of rotation is directly related to the number of input pulses applied.
In this presentation, Lin Engineering will cover common stepper motor applications, issues that can arise within those applications, and stepper modifications that can help resolve those problems. Stepper motors are used in a multitude of applications in many different industries. Steppers can be applied to printers, robotics, security cameras, conveyor belts and aircraft in industries like automation, medical, surveillance, and renewable energy just to name a few.
Each application is unique and the stepper motor must adapt to each situation. Due to the mechanical and environmental requirements from each system, a number of issues and failures can arise when stepper motors are introduced into such applications. Lin Engineering will discuss the root causes of issues like vibration, excessive heat, Back EMF, inertia mismatch and step loss that are seen while using a stepper motor. Lin Engineering will also explain how to resolve the problems through modifications and describe the effects of adding gearboxes, encoders, lead screws, vacuum and additional environmental modifications to a stepper motor.
Why to Watch:
Learn what modifications are required of stepper motors in certain applications.
Learn what common issues arise from different applications.
Learn what applications a stepper motor can be applied to.
Learn how to resolve common application issues through stepper modifications.
Variable Frequency Drive Vs Servo Drive Systemsoftconsystem
The principal primary concern that separates Servo Drives from VFD is the encoder. While Servo Drives can’t work without an encoder for electronic commutation, a VFD can turn out entirely great without it.
BLDC motors are used widely due to various advantages.
This slide includes construction, working, modes of operation and braking, and applications. We also compare it with Brushed DC motor and Induction Motor.
Stepper Motor Types, Advantages And Applicationselprocus
A stepper motor is an electromechanical device which converts electrical pulses into discrete mechanical movements. The shaft or spindle of a stepper motor rotates in discrete step increments when electrical command pulses are
applied to it in the proper sequence. The motors rotation has several direct relationships to these applied input pulses. The sequence of the applied pulses is directly related to the direction of motor shafts rotation. The speed of the
motor shafts rotation is directly related to the frequency of the input pulses and the length of rotation is directly related to the number of input pulses applied.
In this presentation, Lin Engineering will cover common stepper motor applications, issues that can arise within those applications, and stepper modifications that can help resolve those problems. Stepper motors are used in a multitude of applications in many different industries. Steppers can be applied to printers, robotics, security cameras, conveyor belts and aircraft in industries like automation, medical, surveillance, and renewable energy just to name a few.
Each application is unique and the stepper motor must adapt to each situation. Due to the mechanical and environmental requirements from each system, a number of issues and failures can arise when stepper motors are introduced into such applications. Lin Engineering will discuss the root causes of issues like vibration, excessive heat, Back EMF, inertia mismatch and step loss that are seen while using a stepper motor. Lin Engineering will also explain how to resolve the problems through modifications and describe the effects of adding gearboxes, encoders, lead screws, vacuum and additional environmental modifications to a stepper motor.
Why to Watch:
Learn what modifications are required of stepper motors in certain applications.
Learn what common issues arise from different applications.
Learn what applications a stepper motor can be applied to.
Learn how to resolve common application issues through stepper modifications.
Variable Frequency Drive Vs Servo Drive Systemsoftconsystem
The principal primary concern that separates Servo Drives from VFD is the encoder. While Servo Drives can’t work without an encoder for electronic commutation, a VFD can turn out entirely great without it.
BLDC motors are used widely due to various advantages.
This slide includes construction, working, modes of operation and braking, and applications. We also compare it with Brushed DC motor and Induction Motor.
Industrial Robots, Robot Anatomy,Joints, Robot Configurations, Robot Actuators/ Drive systems,Robot programming, Teach pendant Programming, Lead through Programming, Robot control systems,Applications,Advatages
This PPT gives information about:
1.Practical building simple wheeled mobile robots
2. Timeline
3. Classification
4. Robot Accessories
5. Robot Configuratin
6. Control Methods
Vibrant Technologies is headquarted in Mumbai,India.We are the best Robotics training provider in Navi Mumbai who provides Live Projects to students.We provide Corporate Training also.We are Best Robotics classes in Mumbai according to our students and corporators
Acetabularia Information For Class 9 .docxvaibhavrinwa19
Acetabularia acetabulum is a single-celled green alga that in its vegetative state is morphologically differentiated into a basal rhizoid and an axially elongated stalk, which bears whorls of branching hairs. The single diploid nucleus resides in the rhizoid.
Normal Labour/ Stages of Labour/ Mechanism of LabourWasim Ak
Normal labor is also termed spontaneous labor, defined as the natural physiological process through which the fetus, placenta, and membranes are expelled from the uterus through the birth canal at term (37 to 42 weeks
2024.06.01 Introducing a competency framework for languag learning materials ...Sandy Millin
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This webinar will introduce you to my framework, highlighting the key competencies I identified from my research. It will also show how anybody involved in language teaching (any language, not just English!), teacher training, managing schools or developing language learning materials can benefit from using the framework.
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1. The basics of
robotic motion
Robotic motions rely on electrical, pneumatic
or hydraulic power, and digital controllers.
T
here are all types of industrial robots, and most can be broken down into a handful
of basic components. One of the most basic are the drives and the controls. The
drive provides power and can be electric, hydraulic, or pneumatic, while the
controller determines how that power is used to move arms and actuators which
carry effectors or tools to the workpiece.
Let’s step through the basics, taking a look first at Level II: Path Control: At this level, separate
controllers. movements along the planes (determined in Level I)
are combined into desired trajectories or paths.
Controllers Level III: Main Control: At this level, written
Controller coordinates all the movements of the instructions from a human programmer defining
robot’s mechanical actuators. They also receive input the tasks required are interpreted and reconstructed
from the immediate environment through various so that Level II controllers can understand them.
sensors. Machine vision, for example, gives robots In other words, the instructions are combined with
eyes to “see” objects, patterns, and whether an object various sensory signals and translated into the more
is properly orientated for the next step in assembly. elementary instructions that Level II can understand
These days, controllers all contain a digital micro- and carry out.
processor linked to inputs and outputs, including Robots can be further classified in a number of
monitoring devices. ways, depending on their size, tasks, industry, and
Commands issued by controllers activate motion- use. For engineers and designers, robots are usu-
control devices consisting of various sub-controllers, ally broken down into three classifications: types of
amplifiers, and actuators. Actuator are motors or control, types of drives, and the shape of the work
valves that converts power into movement of the envelope.
robot. Movements are initiated by a series of instruc-
tions or program stored in the controller’s memory. Type of control
Controllers usually have three levels of hierarchi- Robots traditionally use one of two control sys-
cal control. In a hierarchical-control scheme, levels tems: non-servo and servo. The earliest robots were
of organization are assigned to various sub-control- non-servo, which are considered non-intelligent Presented by
lers. Each level sends control signals to the level be- robots. Servo robots, however, are classified as either
low while getting feedback and instructions from the intelligent or highly intelligent, with the main differ-
level above. Levels become more elemental as they ence between intelligent and highly intelligent ro-
moves toward the actuator. bots being the level of awareness its sensors give it.
T h e c om m on t h re e c ont rol l e ve l s are : Non-Servo robots, the simplest robots, are often Sponsored by
Level I: Actuator Control: Here’s where separate referred to as “limited sequence,” “pick-and-place,”
movements of the robot along various planes, such or “fixed-stop” robots. They operate in open-loop
as the X, Y, and Z axes, are generated. systems where there is no feedback that lets the ro-
www.micromo.com 1 january 2012
2. A six-axis articulated-arm bot compare pro- ity. In a sense, a servomechanism detects and
robot from Epson uses a series
grammed (desired) corrects for errors.
of electric drives to move
the various joints and positions to actual Servo robots are:
give the robot its positions. • Relatively expensive to purchase, operate,
dexterity. A good example and maintain.
of an open-loop sys- • Us e a s ophisticated, clos ed-lo op
tem is the operating controller.
cycle of a car-wash machine. At the begin- • Have a wide range of capabilities.
ning of the operation, the car is hooked • Can transfer objects from one point to
up to a chain that moves the car through a another, as well as along a controlled, continu-
tunnel of hoses, cleaning brushes, and soap ous path.
spreaders. The machine stops when the car • Can interpret and use sophisticated
pops out the other end of the tunnel. Such a programming.
car wash is considered an open-loop system • Use a manipulator arm programmed to
for two reasons: avoid obstructions within the work envelope.
• Neither cars or anything else is ever ex-
amined by sensors during the washing cycle Actuator drive types
to see if they are clean. In other words, there is Another common way of classifying ro-
no feedback. bots is by the type of drive used by its actua-
• And cycle length is preset. It is not ad- tors. Most robot use ether electric, pneumatic
justed to compensate for the amount of dirt or hydraulic actuators.
remaining on the car or exactly how large a Electric drives encompass three kinds of
car is going through the washer. The cycle and motors: ac servo motors, dc servo motors,
all it attributes are predetermined. and stepper motors. Many newer robots use
Non-servo robots have limited number of servo motors rather than hydraulic or pneu-
movements, usually established by a mechani- matic ones. Small and medium-size robots
cal stop. These types of robots do well at repet- commonly use dc servo motors. Larger ro-
itive tasks, such as material transfer. bots rely on ac servos for their high torque
In general, non-servo robots are: capabilities,
• Relatively inexpensive com- Stepper motors are incrementally con-
pared to servo robots. trolled dc synchronous motors. They are rarely
• Simple to understand, used in commercial industrial robots, but are
program, operate, and commonly found in educational robots.
maintain. Robots that use electric drives take up less
• Precise and reliable. floor space, and their energy source, electric-
• Capable of fairly high ity, is readily available compared to hydrau-
speeds of operation. lic and pneumatic power. However, conven-
• Limited to relatively tionally geared drives suffer from backlash,
simple programs. friction, compliance, and wear. These prob-
Servo Robots use feed- lems reduce accuracy, torque control, and dy-
back so they are consid- namic response, while increasing the need for
ered closed-loop devices. regular maintenance. They also limit the top
In closed-loop devices, speed on longer moves. And heavy enough
feedback sent to the loads will stall (stop) the motor, which can
servo amplifier af- cause damage.
fects the output. Electric motors have relatively poor pow-
Servo amps trans- er-to-wight ratios, compared to hydralulic
A SCARA (selective compliant
articulated robot arm), such as this
late signals from and pneumatic drives. This means a bigger,
electrically-driven one from Epson, controllers into heavier motor must be mounted on the robot
uses a parallel-axis joint layout, motor voltages and arm when a large amount of torque is needed,
making it slightly compliant in the X-Y current signals. even if it’s needed for just a small portion of
direction but rigid in the Z direction. Servo amplifi- the total movement.
And the articlated arm lets it extend
into confined areas or retract or “fold
ers in motion- The rotary motion of most electric drives
up” out of the way. This can be an control application must be geared down so that they can pro-
advantage when moving parts from for robots provide vide the speed or torque needed by the arm
place to place and for loading or precise control of or effector. However, manufacturers are now
unloading in enclosed areas. position or veloc- offering direct-drive motors on robots, which
www.micromo.com 2 january 2012
3. eliminate some of these limitations and prob-
lems. These high-torque motors drive arms The market for robots
directly and do not need reducer gears. In a recent market-research study, Global Industry Analysts Inc. San Jose,
The basic construction of a direct-drive Calif., reported that the worldwide market for industrial robotics will hit
motor couples the motor with the arm seg- 143,000 units by 2015 and that most of the growth in robots will come from
ment being moved, and this eliminates back- “expanding application possibilities, technology developments, rising value
lash, reduces friction, and increases the me- propositions, demographic shifts, and ensuing labor shortages.”
chanical stiffness of the drive mechanism. In 2008 and 2009, a drop in manufacturing and industrial production
Using direct-drive motors in robots lets limited demand for new robots. This was particularly noticeable in the auto-
motive, consumer goods, semi-conductor and electronics, and rubber and
engineers come up with more streamlined
plastic industries. For example, there was a major drop in new vehicle sales
designs. Maintenance is also reduced. Ro-
in the automotive industry, one of the largest user of robotics.
bots using direct-drive motors can operate at But the precipitous drop in robotics growth in the auto sector turned out
higher speeds and with greater accuracy than to be largely temporary. And the recession has not changed the economic
conventional electric-drive motors. fundamentals of robotics. In other words, robots still give manufacturers ad-
vantages in terms of production and labor cost efficiency.
Hydraulic drives The report credits the quick resurgence in spending on robots to the
Many early robots were driven by hydrau- accumulation of postponed and deferred orders, as well as manufacturers
lics. A conventional hydraulic drive consists of increasing their investment in plant renovation, modernization, and capac-
a pump connected to a reservoir tank, control ity expansions. The growth in high-volume toy manufacturing and medi-
valves, and a hydraulic actuator, as well as a cal and healthcare should also build demand for industrial robots over the
next few years as these sectors look to benefit from increased automation.
working fluid. Hydraulic drives can gener-
And demographic trends, especially the aging populations in most western
ate linear and rotary motion using much sim-
countries as well as Japan will spur growth in robots as companies strive to
pler arrangements than conventional electric maintain production with smaller work forces.
drives. One advantage of hydraulics over elec- Assembly-line tasks represents the largest application market for robots
tric drives is that the storage tank, in effect, can worldwide. Welding, however, remains a key contributor to volume sales for
supply a large amount of instant power, which robots in North America and Europe.
is not available from electric drives. Technological advances in robotics in areas such as artificial intelligence,
Other advantages include precise motion machine vision, and distributed motion control will let robots perform a
control over a wide range of speeds and the wider range of tasks independently. These advances will make industrial ro-
ability to handle heavier loads on the end of bots useful and economical, boosting demand for them.
the manipulator arm. They can also be used According to GIA’s report, Asia-Pacific will be the fastest growing regional
market, with sales of industrial robots growing at 9.6% annually for the next
around explosive materials and are not easily
five years. The markets in that area pushing demand will be countries such
damaged when quickly stopped while carry-
as South Korea and China, which host some of the leading electronics manu-
ing a heavy load. However, they are expensive facturers in the world.
to purchase and maintain, and are not energy Increases in outsourcing of manufacturing to low-cost locations such as
efficient. Hydraulic actuator drivers are also China and India will also build demand for robots in the region.
noisier than electric drives and are not recom- Major players in the market include ABB Limited, Adept Technology,
mended for clean-room environments due to Inc., American Robot Corp., Denso Wave Inc., Evolution Robotics, Inc., Fanuc
the possibility of hydraulic fluid leaks. Corp., iRobot Corp., Kawasaki Robotics (USA) Inc, Kuka Roboter GmbH, Pana-
sonic Welding Systems Co., Ltd., Nachi-Fujikoshi Corp.n, RoboGroup Tek Ltd.,
Pneumatic drives Rockwell Automation Inc, ST Robotics, Staubli Corporation, and Yaskawa
Pneumatic drives use of air-driven actua- Electric Corp.
tors. And because air is a fluid, many of the
same principles that apply to hydraulic drives
apply to pneumatic drives. For example, atmospheres. However, since air is compress-
pneumatic and hydraulic motors and cylin- ible, precise placement and positioning re-
ders are very similar. quire additional components to achieve the
Most industrial plants have compressed- smooth control possible with a hydraulic
air pipes running throughout assembly areas, system. It is also difficult to keep the air as
so compressed air is not only economical, it clean and dry as the control system requires.
is readily available. This makes it easier and Robots that use pneumatic actuator drives
less costly to install robots that use pneu- are noisy and vibrate as the air cylinders and
matic actuator drives than hydraulic robots. motors stop. For lightweight pick-and-place
Pneumatic actuator drives work at high applications that require both speed and ac-
speeds and are most useful for small-to-me- curacy, a pneumatic robot is potentially a
dium loads. They are economical to operate good choice.
and maintain and can be used in explosive
www.micromo.com 3 january 2012
4. while others are irregular, and some robots
may have several different work envelopes.
The four major configurations that deter-
mine work envelope shape are: revolute,
Cartesian, cylindrical, and spherical. Here’s
a look at each:
Revolute configuration (articulated or
jointed arm): This is the most common.
These robots are often referred to as being
anthropomorphic because their movements
resemble those of a human arm and upper
torso. Rigid segments take on the roles of the
forearm and upper arm while various joints
mimic actions of the wrist, elbow, and shoul-
der. A joint referred to as the sweep repre-
sents the waist. A revolute robot generally
has an irregularly shaped work envelope.
Revolute configurations can be further
broken down into two formats: vertically
articulated and horizontally articulated.
Vertically articulated robots usually have
Working envelope five rotary joints. Horizontally articulated
configuration generally has one vertical or
linear joint and two rotary joints, and are
commonly called SCARA (selective compli-
ance assembly robot arm) configurations.
SCARA robots are fairly yielding in horizon-
tal motions, but rigid in vertical motions.
SCARA robots are well suited for operations
in which little vertical motion is needed, but
significantly more horizontal motion is re-
quired. Such operations include assembly
Here is an example of a working envelope work where parts are taken from one loca-
for an articlated-arm robot. It shows the tion, perhaps a bin, and moved nearly hori-
maximum vertical and horizontal reach zontally to the product being assembled.
of the arm as well as areas the arm will
sweep through.
The revolute configuration is far and
away the most flexible in terms of operations
and has the largest work envelope of all tra-
The work envelope
ditional configurations.
Another way to discriminate between However, revolute robots need sophis-
robots is based on their work envelopes or ticated and more expensive controllers.
the volume of space that can be reached Programming is also more complex. Other
by the robot’s effector. In general, the en- considerations engineers must taken into
velope shape and size is a function of the account is that the revolute robot’s posi-
coordinate system used by the robot’s tional accuracy, load capacity, dynamics,
arms and manipulators, and the arrange- and repeatability vary with the location in
ment of joints and length of the manip- the work envelope. The robot can also be-
ulator’s segments. Work envelopes also comes less stable as when the arm extends to
vary from one manufacturer to another, its maximum reach.
depending on type of manipulator or arm Cartesian configuration: Arm move-
used. And combining different configu- ments of robots using the Cartesian configu-
rations in a single robot can also create ration can be described by the three tradi-
new working envelopes. Engineers should tional axis: X, Y, and Z, giving them a rectan-
know the application and the exact work gular work envelope.
envelope before choosing a specific robot Movements of the arm and its joints can
configuration. start and stop simultaneously along all three
Some work envelopes are geometric, axes, so motion at the tool tip or effector is
www. micromo.com 4 january 2012
5. smooth. This lets
such robots move
directly to specific
points instead of
following trajecto-
ries parallel to each
axis.
One advantage of
robots with a Carte-
sian configuration
is that their totally
linear movement This single-stage
allows for simpler pneumatic robot from
controls, They also Max Robot was built
have a high degree to support injection
molding. A special arm
of mechanical rigid- lets it remove runners
ity, accuracy, and re- and sprues. It can carry
peatability. They can up to 4.5 lb
carry heavy loads,
and this weight lift-
ing capacity does
not vary at different locations within the work
envelope. As to disadvantages, Cartesian ro-
bots are generally limited in their movement to
a small, rectangular work space.
Cylindrical configurations: Cylindrical
robots consists of a vertical post with a sliding
arm mounted at 90°, making it parallel to the
ground, The stationary post is often mounted
so that it can rotate. The sliding arm robot
moves in and out, and can move up and down
on the carriage that attaches it to the vertical
post. Movement along the three axes traces out
the cylindrical work envelope, which is usually
larger than the envelope of Cartesian robots. This hydrualically
Cylindrical robots are well suited for pick-and- lifting capabilities. Spherical robots are well driven servo-robot
place operations. suited to applications in which only a small has a rotary arm
The downside of cylindrical robot includes amount of vertical movement is needed, such with two degrees
of freedom.
reduced mechanical rigidity due to the rotary as loading and unloading a punch press. Its
axis needing to overcome inertia when rotat- disadvantages include reduced mechanical ri-
ing. This gets amplified when the robots is car- gidity, limited vertical mobility, and the need
rying a heavy load and the sliding arm is fully for more sophisticated control systems than ei-
extended. Repeatability and accuracy is also ther the Cartesian or cylindrical robots. These
reduced in the direction of rotary movement. robots also suffer form the same problems with
Cylindrical robots need more advanced con- inertia and accuracy cylindrical robots.
trols than Cartesian robots. Many industrial robots are hybrids of these
Spherical configuration (polar): These four basic types. Robot designers can always
robots resemble turrets on military tanks. A make the base rotate or vertically collapse and
pivot point gives the robot vertical movement, expand, or add additional joints and wrists
while a telescoping boom (the “gun barrel” of to make the robot more nimble, tailored to a
the tank) provides variable reach by extend- specific task, or to the amount of space needed
ing or retracting the effector. Rotary motion to install a robot. And for even more flexibility,
results from the turret or base turning. industrial robots can be mounted on walls and
The spherical configuration generally pro- ceilings, as well as floors. MD
vides a larger work envelope than Cartesian or
cylindrical configurations. The spherical de-
sign is also simple and provides good weight-
www.micromo.com 5 january 2012