SlideShare a Scribd company logo

Ch-5.0_Robot Technology - CIM.pptx

Download as PPTX, PDF
D
DrGaurangJoshi2

This document discusses industrial robots and their components and characteristics. It covers topics such as definitions of automation and robotics, different types of industrial robots, robot anatomy, configurations, power sources, technical features like work volume and precision of movement. Some key points discussed include that robots are a form of programmable automation, the main components of robots include manipulators, end effectors, actuators, sensors, controllers and software. Common robot configurations are polar, cylindrical, cartesian and jointed arm. Hydraulic and electric are main power sources. Precision is described by spatial resolution, accuracy and repeatability.

1 of 86
Department of Mechanical Engineering P.S. Ujeniya Unit no 6 Unit title RT CAM - 2171903 ROBOTTECHNOLOGY
INDUSTRIAL ROBOTS:  Automation and robotics are closely related technologies.  Automation is concerned with the use of mechanical, Electronics and computer based systems in the operation and control of production.  Examples of this technology include transfer lines, mechanized assembly machines, feedback control systems, NC machine tools and robots.  Accordingly, robotics is a form of industrial automation.
AUTOMATION AND ROBOTICS:  There are three broad classes of industrial automation: 1. Fixed automation 2. Programmable automation 3. Flexible automation
Relationship between fixed automation, programmable automation and flexible automation
 Of the three types of automation, robotics coincides most closely with programmable automation.  An industrial robot is a general-purpose, programmable machine which possesses certain anthropomorphic, or humanlike, characteristics.  The most typical humanlike characteristic or present-day robots is their movable arms.  The robot can be programmed to move its arm through a sequence of motions in order to perform some useful task.  The programming feature allows robots to be used for a variety of different industrial operations, many of which involve the robot working together with other pieces of automated or semi automated equipments.  These operations include machine loading and unloading, spot welding and spray painting. RT
 The “official” definition of an industrial robot is provided by the Robotics Industries Association (RIA), formerly the Robotics Institute of America (RIA):  “An industrial robot is a reprogrammable, multifunctional manipulator designed to move material, parts, tools, or special devices through variable programmed motions for the performance of a variety of tasks.”  This definition reinforces that industrial robots should be classified as a form of programmable automation.  While the robots themselves are examples of programmable automation, they are sometimes used in flexible automation and even fixed automation systems. RT
ROBOT ANATOMY:  Robot anatomy is concerned with the physical construction of the body, arm and wrist of the machine.  Generally, robot body is attached to the base and the arm assembly is attached to the body.  At the end of the arm is the wrist.  The wrist consists of a number of components that allow it to be oriented in a variety of positions.  Relative movements between the various components of the body, arm and wrist are provided by a series of joints.  These joint movement usually involve either rotating or sliding motions.
 The body, arm and wrist assembly is sometimes called the manipulator.  Attached to the robot’s wrist is a hand. The technical name for the hand is “End effector”.  The end effector is not considered as the part of the robot’s anatomy.  The arm and body joints of the manipulator are used to orient the end effector.
CLASSIFICATION OF ROBOTS  The following is the classification of robots according to the Japanese Industrial Robot Association (JIRA): 1. Class 1: Manual Handling Device - A device with multiple degrees of freedom that is actuated by an operator. 2. Class 2: Fixed sequence Robot: - A device that performs the successive stages of a task according to a predetermined, unchanging method and is hard to modify. 3. Class 3: Variable-Sequence Robot: - Same as class 2, but easy to modify.
4. Class 4: Playback Robot: - A human operator performs the task manually by leading the robot, which records the motions for later playback. - The robot repeats the same motions according to the recorded information. 5. Class 5: Numerical Control Robot: - The operator supplies the robot with a movement program rather than teaching it the task manually. 6. Class 6: Intelligent Robot: - A robot with the means to understand its environment and the ability to successfully complete a task despite changes in the surrounding conditions under which it is to be performed.
ADVANTAGES AND DISADVANTAGES OF ROBOT: Advantages:  Robotics and automation can, in many situations, increase productivity, safety, efficiency, quality and consistency of products.  Robots can work in hazardous environments without the need for life support, comfort, or concern about safety.  Robots needs no environmental comfort, such as lighting, air conditions, ventilation, and noise protection.  Robots work continuously without experiencing fatigue or boredom, do not get mad, do not have hangovers, and need no medical insurance or vacation.
 Robots have repeatable precision at all times, unless something happens to them or unless they wear out.  Robots can be much more accurate than humans. Typical linear accuracies are a few thousands of an inch. New wafer- handling robots have micro inch accuracies.  Robots and their accessories and sensors can have capabilities beyond that of humans.  Robot can process multiple stimuli or tasks simultaneously. Humans can only process one active stimulus.  Robot replace human workers creating economic problems, such as lost salaries, and social problems, such as dissatisfaction and resentment among workers. ADVANTAGES AND DISADVANTAGES OF ROBOT:
Disadvantages  Robots lack capability to respond in emergencies, unless the situation is predicted and the response is included in the system. Safety measures are needed to ensure that they do not injure operator and machines working with them. This includes: - Inappropriate or wrong responses - A lack of decision making power - A loss of power - Damage to the robot and other devices - Human injuries ADVANTAGES AND DISADVANTAGES OF ROBOT:
 Robots, although superior in certain senses, have limited capabilities in - Degrees of freedom - Dexterity - Sensors - Vision systems - Real-time response  Robots are costly, due to - Initial cost of equipment - Installation costs - Need for training - Need for programming
ROBOT COMPONENTS:
1. Manipulator or Rover: - This is the main body of the robot and consists of the links, the joints, and other structural elements of the robot. 2. End effector: - This is the part that is connected to the last joint (hand) of a manipulator, which generally handles objects, makes connection to other machines, or performs the required task. 3. Actuators: - Actuators are the “muscles” of the manipulators. Common types of actuators are servomotors, stepper motors, pneumatic cylinders and hydraulic cylinders. ROBOT COMPONENTS:
4. Sensors: - Sensors are used to collect information about the internal state of the robot or to communicate with the outside environment. - Robots are equipped with external sensory devices such as a vision system, touch and tactile sensors, speech synthesizers etc. which enable the robot to communicate with the outside world. 5. Controller - The controller is rather similar to cerebellum and although it does not have the power of brain, it still controls motion. - The controller receives its data from the computer, controls the motion of the actuators and coordinates the motions with the sensory feedback information. ROBOT COMPONENTS:
6. Processor: - The processor is the brain of robot. - It calculates the motions of the robot’s joints, determines how much and how fast each joint must move to achieve the desired location and speeds, and oversees the coordinated actions of the controller and sensors. - Processor is generally a computer which works like all other computers, but is dedicated to a single purpose. ROBOT COMPONENTS:
7. Software: - There are perhaps three groups of software that are used in robot. - One is operating system, which operates computer. - The second is the robotic software, which calculates the necessary motions of each joint based on the kinematic equations of the robot. This information is sent to the controller. - The third group is the collection of routines and application programs that are developed in order to use the peripheral devices of the robots, such as vision routines, or to perform specific tasks. ROBOT COMPONENTS:
ROBOT PHYSICAL CONFIGURATIONS:  Industrial robots are available in a wide variety of sizes, shapes and physical configurations.  The vast majority of today’s commercially available robots possess one of the four basic configurations: 1. Polar configuration 2. Cylindrical configuration 3. Cartesian coordinate configuration 4. Jointed-arm configuration
1. POLAR CONFIGURATION:  The polar configuration uses a telescoping arm that can be raised or lowered about a horizontal pivot.  The pivot is mounted on a rotating base.  These various joints provide the robot with the capability to move its arm within a spherical space, and hence the name “spherical coordinate robot” is sometimes applied to this type.  A number of commercial robots posses the polar configuration.  Examples – - Unimate 2000 series - MAKER 110
2. CYLINDRICAL CONFIGURATION:  The cylindrical configuration, uses a vertical column and a slide that can be moved up and down along the column.  The robot arm is attached to the slide so that it can be moved radially with respect to the column.  By rotating the column, the robot is capable of achieving a work space that approximates a cylinder.
3. CARTESIAN COORDINATE CONFIGURATION:  The Cartesian coordinate robot, uses three perpendicular slides to construct the x, y and z axes.  Other name are sometimes applied to this configuration, including ‘xyz robot’ and ‘rectilinear robot’.  By moving the three slides relative to one another, the robot is capable of operating within a rectangular work envelope.
 Examples- IBM RS-1 robot (Model 7565)  The RS-1, because of its appearance and construction, is occasionally referred to as a “box” configuration.  “Gantry” robot is another name used for Cartesian robot that are generally large and possess the appearance of a gantry type crane.
4. JOINTED ARM CONFIGURATION:  This configuration is similar to that of human arm.  It consists of two straight components, corresponding to the human forearm and upper arm, mounted on a vertical pedestal.  These components are connected by two rotary joints corresponding to the shoulder and elbow.  A wrist is attached to the end of the forearm, thus providing several additional joints.
 A special version of the jointed arm robot is the SCARA, whose shoulder and elbow joints rotate about vertical axes.  SCARA stands for - ‘Selective Compliance Assembly Robot Arm’.  This configuration provides substantial rigidity for the robot in the vertical direction, but compliance in the horizontal plane.  This makes it ideal for many assembly tasks.
COMPARISION OF PHYSICAL CONFIGURATIONS:  There are relative advantages and disadvantages to the four basic robot anatomies simply because of their geometries.  In terms of repeatability of motion (the capability to move to a taught point in space with minimum error), the box-frame cartesian robot probably possesses the advantage because of its inherently rigid structure.  In terms of reach (ability of the robot to extend its arm significantly beyond its base), the polar and jointed are configuration have the advantage.  The cylindrical configuration and the gantry xyz robot can be designed for high-rigidity and load- carrying capacity.  For machine-loading applications, the ability of the robot to reach into a small opening without interference with the sides of the opening is important. The polar configuration and the cylindrical configuration possess a natural geometric advantage in terms of this capability.
ROBOTIC POWER SOURCES:  Commercially available industrial robots are powered by one of the three types of drive systems. 1. Hydraulic drive 2. Electric drive 3. Pneumatic drive  Hydraulic drive and electric drive are the two main types of drives used on more sophisticated robots.
HYDRAULIC DRIVE:  Hydraulic drive is generally associated with larger robots, such as the Unimate 2000 series.  The usual advantage of the hydraulic drive system are that it provides the robot with greater speed and strength.  The disadvantages of the hydraulic drive system are that it typically adds to the floor space required by the robot, and that a hydraulic system is inclined to leak oil which is a nuisance.  Hydraulic drive systems can be designed to actuate either rotational joints or linear joints.  Rotary vane actuators can be used to accomplish linear motion.
ELECTRIC DRIVE:  Electric drive systems do not generally provide as much speed or power as hydraulic system.  However, the accuracy and repeatability of electric drive robots are usually better.  Consequently, electric robots tend to be smaller, requiring less floor space, and their applications tend toward more precise work such as assembly.  The MAKER 110 is an example of an electric drive robot that is consistent with these tendencies.  Electric drive robots are actuated by dc stepping motors or dc servomotors. These motors are ideally suited to the actuation of rotational joints through appropriate drive train and gear systems.  Electric motors can also be used to actuate linear joints (telescoping arms) by means of pulley systems or other translational mechanisms.
 The economics of the two types of drive systems are also a factor in the decision to utilize hydraulic drive on large robots and electric drive on smaller robots.  It turns out that the cost of an electric motor is much more proportional to its size, whereas the cost of a hydraulic drive system is somewhat less dependent on its size.  As shown in the figure, there is a hypothetical break-even point, below which it is advantageous to use electric drive and above which it is appropriate to use hydraulic drive.  So, there is a trend in the design of industrial robots toward all electric drives, and away from hydraulic robots.
Cost vs. size for electric drive and hydraulic drive
PNEUMATIC DRIVE:  Pneumatic drive is generally reserved for smaller robots that possess fewer degrees of freedom (two- to four- joint motions).  These robots are often limited to simple “pick and place” operations with fast cycles.  Pneumatic power can be readily adapted to the actuation of piston devices to provide translational movement of sliding joints.  It can also be used to operate rotary actuators for rotational joints.
TECHNICAL FEATURES: 1. Work volume 2. Precision of movement a) Spatial resolution b) Accuracy c) Repeatability 3. Speed of movement 4. Weight carrying capacity (pay load)
WORK VOLUME:  The term "work volume" refers to the space within which the robot can operate.  To be technically precise, the work volume is the spatial region within which the end of the robot's wrist can be manipulated.  Robot manufacturers have adopted the policy of defining the work volume in terms of the wrist end, with no hand or tool attached.  The work volume of an industrial robot is determined by its physical configuration, size and the limits of its arm and joint manipulations.
 The work volume of a Cartesian coordinate robot will be rectangular.  The work volume of a cylindrical coordinate robot will be cylindrical.  A polar coordinate configuration will generate a work volume which is a partial sphere.  The work volume of a jointed arm robot will be somewhat irregular, the outer reaches generally resembling a partial sphere. WORK VOLUME:
The work volumes for various anatomies (a) polar (b) cylindrical (c) cartesian
PRECISION OF MOVEMENT:  The precision with which the robot can move the end of its wrist is a critical consideration in most applications.  In robotics, precision of movement is a complex issue, and it is described as three attributes: 1. Spatial resolution 2. Accuracy 3. Repeatability  These attributes are generally interpreted in terms of the wrist end with no end effector attached and with the arm fully extended.
SPATIAL RESOLUTION:  The term "spatial resolution" refers to the smallest increment of motion at the wrist end that can be controlled by the robot.  This is determined largely by the robot's control resolution, which depends on its position control system and/or its feedback measurement system.  In addition, mechanical inaccuracies in the robot's joints would tend to degrade its ability to position its arm.  The spatial resolution is the sum of the control resolution plus these mechanical inaccuracies.
 The factor determining control resolution are the range of movement of the arm and the bit storage capacity in the control memory for that movement.  The arm movement must be divided into its basic motions or degrees of freedom, and the resolution of each degree of freedom is figured separately. Then the total control resolution is the vector sum of each component.
ACCURACY:  The accuracy of the robot refers to its capability to position its wrist end (or a tool attached to the wrist) at a given target point within its work volume.  Accuracy is closely related to spatial resolution, since the robot's ability to reach a particular point in space depends on its ability to divide its joint movements into small increments.  According to this relation, the accuracy of the robot would be one half the distance between the two adjacent resolution points.  The robot's accuracy is also affected by mechanical inaccuracies, such as deflection of its components, gear inaccuracies, and so worth.
REPEATABILITY:  This refers to the robot's ability to position its wrist end (or tool) back to a point in space that was previously taught.  Repeatability is different from accuracy.  The robot was initially programmed to move the wrist end to the target point T. Because it is limited by its accuracy, the robot was only capable of achieving point A. The distance between points A and T is the accuracy.  Later, the robot is instructed to return to this previously programmed point A. However, because it is limited by it repeatability, it is only capable of moving to point R.  The distance between points R and A is a measure of the robot's repeatability.  As the robot is instructed to return to the same position in subsequent work cycles, it will not always return to point R, but instead will form a cluster of positions about point A.
Illustration of Repeatabili ty versus accuracy  Repeatability errors form a random variable.  In general, repeatability will be better than accuracy.  Mechanical inaccuracies in the robot‘s arm and wrist components are principal sources of repeatability errors.
END EFFECTORS:  In the terminology of robotics, an end effector can be defined as a device which is attached to the robot's wrist to perform a specific task.  The task might be work part handling, spot welding, spray painting, or any of a great variety of other functions.  The end effector is the special-purpose tooling which enables the robot to perform a particular job.  It is usually custom engineered for that job, either by the company that owns the robot or by the company that sold the robot.  Most robot manufacturers have engineering groups which design and fabricate end effectors or provide advice to their customers on end effector design.  For purposes of organization, we will divide the various types of end effectors into two categories:  grippers and tools
GRIPPERS:  Grippers are used to hold either work parts (in pick-and-place operations, machine loading, or assembly work) or tools.  There are numerous alternative ways in which the gripper can be designed. The most appropriate design depends on the work part or substance being handled. The following is a list of the most common grasping methods used in robot grippers : - Mechanical grippers, where friction or the physical configuration of the gripper retains the object - Suction cups (also called vacuum cups), used for flat objects Magnetized gripper devices, used for ferrous objects - Hooks, used to lift parts off conveyors - Scoops or ladles, used for fluids, powders, pellets, or granular substances
Sample gripper designs (a) pivot action gripper; (b) slide action gripper; (c) double gripper-pivot action mechanism; (d) vacuum-operated hand GRIPPERS:
OTHER TYPES OF GRIPPERS: 1. Vacuum cups 2. Magnetic grippers 3. Adhesive grippers 4. Hooks, scoops and other miscellaneous devices.
Gripper
TOOLS AS END EFFECTOR:  There are a limited number of applications in which a gripper is used to grasp tool and use it during the work cycle.  In most applications where the robot manipulates a tool during the cycle, the tool is fastened directly to the robot wrist becomes the end effector.  A few examples of tools used with robots are the following: - Spot welding gun - Arc welding tools (and wire-feed mechanisms) - Spray painting gun - Drilling spindle - Routers, grinders, wire brushes - Heating torches
WORK CELL CONTROL:  Industrial robots usually work with other things: processing equipment, work part conveyors, tools, and perhaps, human operators.  Some of the activities occur sequentially, while others take place simultaneously.  To make certain that the various activities are coordinated and occur in the proper sequence, a device called the work cell controller is used (another name for this is workstation controller).  The work cell controller usually resides within the robot and has overall responsibility for regulating the activities of the work cell components.
SENSORS:  Sensors are used to collect information about the internal state of the robot or to communicate with the outside environment.  In a robot, as the links and joints move, sensors such as potentiometers, encoders and resolvers send signals to the controller that allow it to determine where each joint is.  The sensors may be similar in function to that of humans, such as vision, touch, and smell.  In some cases, the sensors may be something humans do not have, such as radioactive sensor.
SENSOR CHARACTERISTICS:  The characteristics of sensors determine the performance, economy, ease of application, and applicability. 1. Accuracy: Accuracy is defined as how close the output of sensor is to the expected value. 2. Repeatability: If the sensor’s output is measured a number of times in response to the same input, the output may be different each time. Repeatability is a measure of how varied the different outputs are relative to each other. 3. Range: Range is the difference between the smallest and the largest outputs the sensor can produce, or the difference between the smallest and the largest inputs with which it can operate properly.
4. Response time (Speed of Response):  Response time is the time that a sensor’s output requires to reach a certain percentage of the total change. It is usually expressed in percentage of total change, such as 95%.  It is also defined as the time required to observe the change in output as a result of a change in input. 5. Sensitivity: The sensitivity is the ratio of a change in output in response to a change in input. Highly sensitive sensors will show larger fluctuations in output as a result of fluctuations in input, including noise. 6. Linearity: Linearity represents the relationship between input variations and output variations. Almost all the devices in nature are somewhat nonlinear, with varying degrees of nonlinearity. Certain devices can be assumed to be linear within a certain range of operation. SENSOR CHARACTERISTICS:
7. Interfacing: The sensor should be easy to interface with other devices such as microprocessors and controller. 8. Reliability: Reliability is the ratio of how many time a system operates properly divided by how many times it is tries. 9. Frequency response: The larger the range of the frequency response, the better the ability of the system to respond to varying input. 10. Cost and Ease of Operation: The cost of purchase, installation and operation of sensor should be as low as possible. The installation and operation of sensor should be simple and easy. 11. Size and Weight: The size and weight of the sensor should be as small as possible. SENSOR CHARACTERISTICS:
TYPES OF SENSORS: SENSORS TECTILE OR CONTACT SENSORS TOUCH SENSORS FORCE SENSORS POSITION OR DISPLACEMENT SENSORS NON-CONTACT SENSORS PROXIMITIY OR RANGE SENSORS ROBOT VISION SYSTEMS VOICE SENSORS
TACTILE SENSORS:  Tactile sensors are divided into following categories. 1. Touch sensors 2. Force sensors 3. Position and displacement sensors Touch sensors:  Touch sensors are devices that send a signal when physical contact has been made.  The simplest form of touch sensor is microswitch, which either turns on or off as contact is made.  These sensors indicated and respond to the presence or absence of an object. They provide the binary output signals.
Force Sensors:  Force sensors are used to measure the magnitude of contact force.  These sensors are analog type sensors in which the output signal is proportional to local force.  Examples- Piezoelectric sensors, force sensing resistors, strain gauges etc. Position and Displacement sensors:  Position sensors are used to measure displacement, both rotary and linear, as well as movements.  In many cases the position information may also be used to calculate velocities.  Examples- Potentiometers, encoders, linear variable differential transformers (LVDT), resolvers etc.
PROXIMITY SENSORS:  Proximity sensors are used to determine that an object is close to another object before the contact is made.  This noncontact sensing is useful in many situation, from measuring the speed of a rotor to navigating a robot.  Examples- Magnetic and eddy current sensors, optical, ultrasonic inductive and capacitive. VISION SENSORS:  Computerized visions systems will be an important technology in future automated factories.  Robot vision is made possible by means of a video camera, a sufficient light source, and a computer programmed to process image data.  The camera is mounted either on the robot or in a fixed position above the robot so that its field of vision includes the robot's work volume.
 The computer software enables the vision system to sense the presence of an object and its position and orientation.  Vision capability would enable the robot to carry out the following kinds of operations: - Retrieve parts which are randomly oriented on a conveyor. - Recognize particular parts which are intermixed with other objects. - Perform visual inspection tasks. - Perform assembly operations which require alignment.  All of these operations have been accomplished in research laboratories. It is merely a matter of time and economics before vision sensors become a common feature in robot applications.
VOICE SENSORS:  Another area of robotics research is voice sensing or voice programming.  Voice programming can be defined as the oral communication of commands to the robot or other machine.  The robot controller is equipped with a speech recognition system which analyzes the voice input and compares it with a set of stored word patterns.  When a match is found between the input and the stored vocabulary word, the robot performs some action which corresponds to that word.  Voice sensors would be useful in robot programming to speed up the programming procedure, just as it does in NC programming.  It would also be beneficial in especially hazardous working environments for performing unique operations such as maintenance and repair work.
ACTUATORS:  Actuators are the muscles of robots.  If links and joints are considered as the skeleton of the robot, the actuators, act as, muscles, which move or rotate the links to change the configuration of robots.  The actuators must have enough power to accelerate and decelerate the links and to carry the loads, yet be light, economical, accurate, responsive, reliable and easy to maintain.
Types of Actuators:  Mechanical actuators  Electric motors - Servomotors - Stepper motors - Direct drive electric motors  Hydraulic actuators  Pneumatic actuators  Shape memory metal actuators  Magnetostrictive actuators
MECHANICAL ACTUATORS:  Mechanical actuators are classified into two types: 1. Linear Mechanical actuators 2. Rotary Mechanical actuators Linear Mechanical Actuators:  Linear mechanical actuators are used to actuate the linear manipulator joints of the robot.  Examples – Rack and pinion - Recirculating ball screws Rotary Mechanical Actuators:  Examples – Timing belts - Gear pairs - Harmonic drives
ELECTRIC MOTORS: DC Motors:  DC motors are common in industry and are reliable and relatively powerful. AC Motors:  Electric AC motors are similar to DC motor, except that the rotor is permanent magnet, the stator houses the winding. Direct Drive Electric Motors:  These motors are designed to deliver a very large torque at very low speeds and with very high resolution.  These motors are intended to be used directly with a joint without any gear reduction.  Direct drive motors are still very expensive and very heavy, but have impressive characteristics.
Servomotors:  In a servomotor, by varying current (or corresponding voltage) the speed torque balance can be maintained.  A servomotor is DC, AC, brushless or even stepper, motor with feedback that can be controlled to move at a desired speed for a desired angle of rotation. Stepper Motors:  Stepper motors are versatile, long- lasting, simple motors that can be used in many applications.  In most applications, the stepper motors are used without feedback.
HYDRAULIC ACTUATORS:  Hydraulic actuators offer a high power to weight ratio, large forces at low speeds, compatibility with microprocessor and electronic controls and can be used in extreme hazardous environments.  A hydraulic system generally consists of the following parts: 1. Hydraulic linear or rotary cylinders and rams 2. A hydraulic pump 3. Electric motors 4. Cooling system 5. Reservoir 6. Valves and connecting hoses 7. Sensors
PNEUMATIC ACTUATORS:  A source of pressurized air is used to power and drive linear or rotary cylinders, controlled by manual or electrically controlled solenoid valves.  Pneumatic actuators are of linear or rotary type.  A linear pneumatic actuators are the single acting or double acting pneumatic cylinders used to actuate the linear joints of the robots.  The cylinders are operated by compressed air at about 35 to 70 bar pressure.  High pressure compressed air runs the pneumatic motors. The torque developed by pneumatic motor actuates the rotary joints.
ROBOT APPLICATIONS:  General Application Characteristics 1. Hazardous or uncomfortable working conditions 2. Repetitive tasks 3. Difficult handling 4. Multishift operation
Application Areas for Industrial Robots: 1. Material transfer 2. Machine loading 3. Welding 4. Spray coating 5. Processing operations 6. Assembly 7. Inspection
1. MATERIAL TRANSFER  Simple pick and place operations  Transfer of workparts from one conveyer to another conveyer  Palletizing operations, in which the robot takes parts from a conveyor and loads them onto pallet in required pattern and sequence  Stacking operation  Loading parts from a conveyor into cartons or boxes  Depalletizing operations, in which the robot takes parts which are arranged on a pallet and loads them onto a conveyor
2. MACHINE LOADING  Machine loading applications are material handling operations in which the robot is required to supply a production machine with raw work parts and/or to unload the finish parts form the machine.  Machine loading is distinguish form a material transfer operation by the fact that the robot works directly with the processing equipments.  Production operations in which robot have been successfully applied to perform the machine loading and unloading function includes: - Die casting - Injection (plastic) molidng - Hot forging - Upsetting or upset forging - Stamping press operations - Machining operations such as turning and milling
3. WELDING:  Spot welding  Arc welding
4. SPRAY PAINTING  Spray painting process poses certain health hazards to the human operator. These are - fumes and mist from the spraying operation - noise from the spray nozzles - fire hazard - possible cancer dangers  For these and other reasons, specialized industrial robots are being used more and more frequently to perform spray painting operations.  Advantages of using robot in this applications are: - safety - Coating consistency - Lower material usage - Less energy used - Greater productivity
5. PROCESSING OPERATIONS:  Drilling  Riveting  Grinding  Polishing  Deburring  Wire brushing  Waterjet cutting
6. ASSEMBLY:  Adaptable-programmable assembly system (APAS)  PUMA (Programmable Universal Machine for Assembly) 7. INSPECTION:  Robots equipped with mechanical probes, optical sensing capabilities, or other measuring devices can be programmed to perform dimensional checking and other forms of inspection operations.
ECONOMIC ANALYSIS FOR ROBOTICS  The economic analysis for any proposed robot project is of considerable importance in most companies because management usually decides whether to install the project on the basis of this analysis.  To perform the economic analysis of a proposed robot project, certain basic information is needed about the project.  This information includes- - the type of project being considered - the cost of the robot installation - the production cycle time - savings and benefits resulting from the project
Cost data required for the analysis:  The cost data required to perform the economic analysis of a robot project divide into two types: 1. Investment costs: - Robot purchase cost - Planning and design cost - installation cost - Special tooling - Miscellaneous costs 2. Operating costs: - Direct labor cost - Indirect labor cost - Maintenance - Utilities - Training
INTERFACING A VISION SYSTEM WITH A ROBOT:  Machine vision is concerned with the sensing of vision data and its interpretation by computer.  The typical vision system consists of the camera and digitizing hardware, a digital computer and hardware and software necessary to interface them with the robot.  This interface hardware and software is often referred to as preprocessor.  The operation of the vision system consists of three functions: 1. Sensing and digitizing image data 2. Image processing and analysis 3. Application  Current typical application of machine vision with robot are for inspection task in high speed production line to accept or reject parts made on the line. Unacceptable parts are ejected from the line by some mechanical device that is communicating with the vision system.
INTELLIGENT ROBOTS:  Artificial Intelligence efforts aim at developing systems that appear to behave intelligently. Often this is described as developing machines that “think”.  Typically this work is carried out as a branch of computer science, although it also contains element of psychology and mathematics.  One of the problems involved with vision systems is the representation of data within the system.  Rather than store pictures of the parts within the vision systems memory, certain features about the objects are stored, such as perimeter, area, number of holes, and so on.
 As the system become more complex and begin to be able to deal in crowded three-dimensional environments it will require greater intelligence on the part of the vision system.  Techniques have been developed which allow vision systems to recognize specific types of objects even when mixed together.  These systems rely heavily on artificial intelligent methods to increase their processing speed.
Ch-5.0_Robot Technology - CIM.pptx

Recommended

Ch-5.0_Robot Technology - CIM.pptx
Ch-5.0_Robot Technology - CIM.pptxCh-5.0_Robot Technology - CIM.pptx
Ch-5.0_Robot Technology - CIM.pptx
PuneetMathur39
 
Fundamental of robotic manipulator
Fundamental of robotic manipulatorFundamental of robotic manipulator
Fundamental of robotic manipulatorsnkalepvpit
 
Computer aided manufacturing robotic systems
Computer aided manufacturing robotic systemsComputer aided manufacturing robotic systems
Computer aided manufacturing robotic systemsPrasanth Kumar RAGUPATHY
 
ROBOTICS.pdf
ROBOTICS.pdfROBOTICS.pdf
ROBOTICS.pdf
srinivasa gowda
 
module 2 operating system for semester 4
module 2 operating system for semester 4module 2 operating system for semester 4
module 2 operating system for semester 4
ksamjish
 
Robot
RobotRobot
Robot
Sujit Regmi
 
Industrial robotics
Industrial roboticsIndustrial robotics
Industrial roboticsKallinath Patil
 
UNIT -5-0001235689- INDUSTRIAL ROBOTICS .ppt
UNIT -5-0001235689- INDUSTRIAL ROBOTICS .pptUNIT -5-0001235689- INDUSTRIAL ROBOTICS .ppt
UNIT -5-0001235689- INDUSTRIAL ROBOTICS .ppt
dharma raja`
 

Recommended

Ch-5.0_Robot Technology - CIM.pptx
Ch-5.0_Robot Technology - CIM.pptxCh-5.0_Robot Technology - CIM.pptx
Ch-5.0_Robot Technology - CIM.pptx
PuneetMathur39
 
Fundamental of robotic manipulator
Fundamental of robotic manipulatorFundamental of robotic manipulator
Fundamental of robotic manipulatorsnkalepvpit
 
Computer aided manufacturing robotic systems
Computer aided manufacturing robotic systemsComputer aided manufacturing robotic systems
Computer aided manufacturing robotic systemsPrasanth Kumar RAGUPATHY
 
ROBOTICS.pdf
ROBOTICS.pdfROBOTICS.pdf
ROBOTICS.pdf
srinivasa gowda
 
module 2 operating system for semester 4
module 2 operating system for semester 4module 2 operating system for semester 4
module 2 operating system for semester 4
ksamjish
 
Robot
RobotRobot
Robot
Sujit Regmi
 
Industrial robotics
Industrial roboticsIndustrial robotics
Industrial roboticsKallinath Patil
 
UNIT -5-0001235689- INDUSTRIAL ROBOTICS .ppt
UNIT -5-0001235689- INDUSTRIAL ROBOTICS .pptUNIT -5-0001235689- INDUSTRIAL ROBOTICS .ppt
UNIT -5-0001235689- INDUSTRIAL ROBOTICS .ppt
dharma raja`
 
Robotics
RoboticsRobotics
Robotics
SHIVAM JAISWAL
 
Introduction to robotics, Laws,Classification,Types, Drives,Geometry
Introduction to robotics, Laws,Classification,Types, Drives,Geometry Introduction to robotics, Laws,Classification,Types, Drives,Geometry
Introduction to robotics, Laws,Classification,Types, Drives,Geometry
Mohammad Ehtasham
 
Introduction about robotics
Introduction about roboticsIntroduction about robotics
Introduction about robotics
VISHNUBEN
 
Industrial robotics pick & place
Industrial robotics pick & placeIndustrial robotics pick & place
Industrial robotics pick & place
Robotics Solutions
 
Pick and place
Pick and placePick and place
Pick and place
bharinalaharidhar
 
ROBOTICS.pdf
ROBOTICS.pdfROBOTICS.pdf
ROBOTICS.pdf
Priya429658
 
Robotics-Asimov's Laws, Mechanical Subsystems, Robot Kinematics, Robot Dynami...
Robotics-Asimov's Laws, Mechanical Subsystems, Robot Kinematics, Robot Dynami...Robotics-Asimov's Laws, Mechanical Subsystems, Robot Kinematics, Robot Dynami...
Robotics-Asimov's Laws, Mechanical Subsystems, Robot Kinematics, Robot Dynami...
Sumanth A
 
presentation on robotic technology
presentation on robotic technologypresentation on robotic technology
presentation on robotic technology
Ashar Gill
 
the role of robots in daily life
the role of robots in daily lifethe role of robots in daily life
the role of robots in daily life
Ashar Gill
 
Industrial robots
Industrial robotsIndustrial robots
Industrial robots
santan chaurasiya
 
Space robotics
Space roboticsSpace robotics
Space robotics
MU
 
Robots
RobotsRobots
Robotsmrscjrobertson
 
Robotics.fair
Robotics.fairRobotics.fair
Robotics.fairkewins
 
Robotics and Automation Introduction
Robotics and Automation IntroductionRobotics and Automation Introduction
Robotics and Automation Introduction
anand hd
 
Robotics
RoboticsRobotics
Robotics
The Avi Sharma
 
Dek3223 chapter 2 robotic
Dek3223 chapter 2 roboticDek3223 chapter 2 robotic
Dek3223 chapter 2 roboticmkazree
 
Summer Training Program Report On Embedded system and robot
Summer Training Program Report On Embedded system and robot Summer Training Program Report On Embedded system and robot
Summer Training Program Report On Embedded system and robot
Arcanjo Salazaku
 
visheshwar oraon robotics presentation
visheshwar oraon robotics presentationvisheshwar oraon robotics presentation
visheshwar oraon robotics presentation
Akash Maurya
 
Industrial robots
Industrial robotsIndustrial robots
Industrial robots
Madan Bhusal
 
Robotics
RoboticsRobotics
Robotics
Dr.R. SELVAM
 
Top 10 Oil and Gas Projects in Saudi Arabia 2024.pdf
Top 10 Oil and Gas Projects in Saudi Arabia 2024.pdfTop 10 Oil and Gas Projects in Saudi Arabia 2024.pdf
Top 10 Oil and Gas Projects in Saudi Arabia 2024.pdf
Teleport Manpower Consultant
 
AKS UNIVERSITY Satna Final Year Project By OM Hardaha.pdf
AKS UNIVERSITY Satna Final Year Project By OM Hardaha.pdfAKS UNIVERSITY Satna Final Year Project By OM Hardaha.pdf
AKS UNIVERSITY Satna Final Year Project By OM Hardaha.pdf
SamSarthak3
 

More Related Content

Similar to Ch-5.0_Robot Technology - CIM.pptx

Robotics
RoboticsRobotics
Robotics
SHIVAM JAISWAL
 
Introduction to robotics, Laws,Classification,Types, Drives,Geometry
Introduction to robotics, Laws,Classification,Types, Drives,Geometry Introduction to robotics, Laws,Classification,Types, Drives,Geometry
Introduction to robotics, Laws,Classification,Types, Drives,Geometry
Mohammad Ehtasham
 
Introduction about robotics
Introduction about roboticsIntroduction about robotics
Introduction about robotics
VISHNUBEN
 
Industrial robotics pick & place
Industrial robotics pick & placeIndustrial robotics pick & place
Industrial robotics pick & place
Robotics Solutions
 
Pick and place
Pick and placePick and place
Pick and place
bharinalaharidhar
 
ROBOTICS.pdf
ROBOTICS.pdfROBOTICS.pdf
ROBOTICS.pdf
Priya429658
 
Robotics-Asimov's Laws, Mechanical Subsystems, Robot Kinematics, Robot Dynami...
Robotics-Asimov's Laws, Mechanical Subsystems, Robot Kinematics, Robot Dynami...Robotics-Asimov's Laws, Mechanical Subsystems, Robot Kinematics, Robot Dynami...
Robotics-Asimov's Laws, Mechanical Subsystems, Robot Kinematics, Robot Dynami...
Sumanth A
 
presentation on robotic technology
presentation on robotic technologypresentation on robotic technology
presentation on robotic technology
Ashar Gill
 
the role of robots in daily life
the role of robots in daily lifethe role of robots in daily life
the role of robots in daily life
Ashar Gill
 
Industrial robots
Industrial robotsIndustrial robots
Industrial robots
santan chaurasiya
 
Space robotics
Space roboticsSpace robotics
Space robotics
MU
 
Robotics.fair
Robotics.fairRobotics.fair
Robotics.fairkewins
 
Robotics and Automation Introduction
Robotics and Automation IntroductionRobotics and Automation Introduction
Robotics and Automation Introduction
anand hd
 
Robotics
RoboticsRobotics
Robotics
The Avi Sharma
 
Dek3223 chapter 2 robotic
Dek3223 chapter 2 roboticDek3223 chapter 2 robotic
Dek3223 chapter 2 roboticmkazree
 
Summer Training Program Report On Embedded system and robot
Summer Training Program Report On Embedded system and robot Summer Training Program Report On Embedded system and robot
Summer Training Program Report On Embedded system and robot
Arcanjo Salazaku
 
visheshwar oraon robotics presentation
visheshwar oraon robotics presentationvisheshwar oraon robotics presentation
visheshwar oraon robotics presentation
Akash Maurya
 
Industrial robots
Industrial robotsIndustrial robots
Industrial robots
Madan Bhusal
 
Robotics
RoboticsRobotics
Robotics
Dr.R. SELVAM
 

Similar to Ch-5.0_Robot Technology - CIM.pptx (20)

Robotics
RoboticsRobotics
Robotics
 
Introduction to robotics, Laws,Classification,Types, Drives,Geometry
Introduction to robotics, Laws,Classification,Types, Drives,Geometry Introduction to robotics, Laws,Classification,Types, Drives,Geometry
Introduction to robotics, Laws,Classification,Types, Drives,Geometry
 
Introduction about robotics
Introduction about roboticsIntroduction about robotics
Introduction about robotics
 
Industrial robotics pick & place
Industrial robotics pick & placeIndustrial robotics pick & place
Industrial robotics pick & place
 
Pick and place
Pick and placePick and place
Pick and place
 
ROBOTICS.pdf
ROBOTICS.pdfROBOTICS.pdf
ROBOTICS.pdf
 
Robotics-Asimov's Laws, Mechanical Subsystems, Robot Kinematics, Robot Dynami...
Robotics-Asimov's Laws, Mechanical Subsystems, Robot Kinematics, Robot Dynami...Robotics-Asimov's Laws, Mechanical Subsystems, Robot Kinematics, Robot Dynami...
Robotics-Asimov's Laws, Mechanical Subsystems, Robot Kinematics, Robot Dynami...
 
presentation on robotic technology
presentation on robotic technologypresentation on robotic technology
presentation on robotic technology
 
the role of robots in daily life
the role of robots in daily lifethe role of robots in daily life
the role of robots in daily life
 
Industrial robots
Industrial robotsIndustrial robots
Industrial robots
 
Space robotics
Space roboticsSpace robotics
Space robotics
 
Robots
RobotsRobots
Robots
 
Robotics.fair
Robotics.fairRobotics.fair
Robotics.fair
 
Robotics and Automation Introduction
Robotics and Automation IntroductionRobotics and Automation Introduction
Robotics and Automation Introduction
 
Robotics
RoboticsRobotics
Robotics
 
Dek3223 chapter 2 robotic
Dek3223 chapter 2 roboticDek3223 chapter 2 robotic
Dek3223 chapter 2 robotic
 
Summer Training Program Report On Embedded system and robot
Summer Training Program Report On Embedded system and robot Summer Training Program Report On Embedded system and robot
Summer Training Program Report On Embedded system and robot
 
visheshwar oraon robotics presentation
visheshwar oraon robotics presentationvisheshwar oraon robotics presentation
visheshwar oraon robotics presentation
 
Industrial robots
Industrial robotsIndustrial robots
Industrial robots
 
Robotics
RoboticsRobotics
Robotics
 

Recently uploaded

Top 10 Oil and Gas Projects in Saudi Arabia 2024.pdf
Top 10 Oil and Gas Projects in Saudi Arabia 2024.pdfTop 10 Oil and Gas Projects in Saudi Arabia 2024.pdf
Top 10 Oil and Gas Projects in Saudi Arabia 2024.pdf
Teleport Manpower Consultant
 
AKS UNIVERSITY Satna Final Year Project By OM Hardaha.pdf
AKS UNIVERSITY Satna Final Year Project By OM Hardaha.pdfAKS UNIVERSITY Satna Final Year Project By OM Hardaha.pdf
AKS UNIVERSITY Satna Final Year Project By OM Hardaha.pdf
SamSarthak3
 
Basic Industrial Engineering terms for apparel
Basic Industrial Engineering terms for apparelBasic Industrial Engineering terms for apparel
Basic Industrial Engineering terms for apparel
top1002
 
14 Template Contractual Notice - EOT Application
14 Template Contractual Notice - EOT Application14 Template Contractual Notice - EOT Application
14 Template Contractual Notice - EOT Application
SyedAbiiAzazi1
 
Industrial Training at Shahjalal Fertilizer Company Limited (SFCL)
Industrial Training at Shahjalal Fertilizer Company Limited (SFCL)Industrial Training at Shahjalal Fertilizer Company Limited (SFCL)
Industrial Training at Shahjalal Fertilizer Company Limited (SFCL)
MdTanvirMahtab2
 
Sachpazis:Terzaghi Bearing Capacity Estimation in simple terms with Calculati...
Sachpazis:Terzaghi Bearing Capacity Estimation in simple terms with Calculati...Sachpazis:Terzaghi Bearing Capacity Estimation in simple terms with Calculati...
Sachpazis:Terzaghi Bearing Capacity Estimation in simple terms with Calculati...
Dr.Costas Sachpazis
 
Standard Reomte Control Interface - Neometrix
Standard Reomte Control Interface - NeometrixStandard Reomte Control Interface - Neometrix
Standard Reomte Control Interface - Neometrix
Neometrix_Engineering_Pvt_Ltd
 
Railway Signalling Principles Edition 3.pdf
Railway Signalling Principles Edition 3.pdfRailway Signalling Principles Edition 3.pdf
Railway Signalling Principles Edition 3.pdf
TeeVichai
 
weather web application report.pdf
weather web application report.pdfweather web application report.pdf
weather web application report.pdf
Pratik Pawar
 
Heap Sort (SS).ppt FOR ENGINEERING GRADUATES, BCA, MCA, MTECH, BSC STUDENTS
Heap Sort (SS).ppt FOR ENGINEERING GRADUATES, BCA, MCA, MTECH, BSC STUDENTSHeap Sort (SS).ppt FOR ENGINEERING GRADUATES, BCA, MCA, MTECH, BSC STUDENTS
Heap Sort (SS).ppt FOR ENGINEERING GRADUATES, BCA, MCA, MTECH, BSC STUDENTS
Soumen Santra
 
DESIGN A COTTON SEED SEPARATION MACHINE.docx
DESIGN A COTTON SEED SEPARATION MACHINE.docxDESIGN A COTTON SEED SEPARATION MACHINE.docx
DESIGN A COTTON SEED SEPARATION MACHINE.docx
FluxPrime1
 
Building Electrical System Design & Installation
Building Electrical System Design & InstallationBuilding Electrical System Design & Installation
Building Electrical System Design & Installation
symbo111
 
AP LAB PPT.pdf ap lab ppt no title specific
AP LAB PPT.pdf ap lab ppt no title specificAP LAB PPT.pdf ap lab ppt no title specific
AP LAB PPT.pdf ap lab ppt no title specific
BrazilAccount1
 
Gen AI Study Jams _ For the GDSC Leads in India.pdf
Gen AI Study Jams _ For the GDSC Leads in India.pdfGen AI Study Jams _ For the GDSC Leads in India.pdf
Gen AI Study Jams _ For the GDSC Leads in India.pdf
gdsczhcet
 
Unbalanced Three Phase Systems and circuits.pptx
Unbalanced Three Phase Systems and circuits.pptxUnbalanced Three Phase Systems and circuits.pptx
Unbalanced Three Phase Systems and circuits.pptx
ChristineTorrepenida1
 
English lab ppt no titlespecENG PPTt.pdf
English lab ppt no titlespecENG PPTt.pdfEnglish lab ppt no titlespecENG PPTt.pdf
English lab ppt no titlespecENG PPTt.pdf
BrazilAccount1
 
Investor-Presentation-Q1FY2024 investor presentation document.pptx
Investor-Presentation-Q1FY2024 investor presentation document.pptxInvestor-Presentation-Q1FY2024 investor presentation document.pptx
Investor-Presentation-Q1FY2024 investor presentation document.pptx
AmarGB2
 
Final project report on grocery store management system..pdf
Final project report on grocery store management system..pdfFinal project report on grocery store management system..pdf
Final project report on grocery store management system..pdf
Kamal Acharya
 
Nuclear Power Economics and Structuring 2024
Nuclear Power Economics and Structuring 2024Nuclear Power Economics and Structuring 2024
Nuclear Power Economics and Structuring 2024
Massimo Talia
 
Cosmetic shop management system project report.pdf
Cosmetic shop management system project report.pdfCosmetic shop management system project report.pdf
Cosmetic shop management system project report.pdf
Kamal Acharya
 

Recently uploaded (20)

Top 10 Oil and Gas Projects in Saudi Arabia 2024.pdf
Top 10 Oil and Gas Projects in Saudi Arabia 2024.pdfTop 10 Oil and Gas Projects in Saudi Arabia 2024.pdf
Top 10 Oil and Gas Projects in Saudi Arabia 2024.pdf
 
AKS UNIVERSITY Satna Final Year Project By OM Hardaha.pdf
AKS UNIVERSITY Satna Final Year Project By OM Hardaha.pdfAKS UNIVERSITY Satna Final Year Project By OM Hardaha.pdf
AKS UNIVERSITY Satna Final Year Project By OM Hardaha.pdf
 
Basic Industrial Engineering terms for apparel
Basic Industrial Engineering terms for apparelBasic Industrial Engineering terms for apparel
Basic Industrial Engineering terms for apparel
 
14 Template Contractual Notice - EOT Application
14 Template Contractual Notice - EOT Application14 Template Contractual Notice - EOT Application
14 Template Contractual Notice - EOT Application
 
Industrial Training at Shahjalal Fertilizer Company Limited (SFCL)
Industrial Training at Shahjalal Fertilizer Company Limited (SFCL)Industrial Training at Shahjalal Fertilizer Company Limited (SFCL)
Industrial Training at Shahjalal Fertilizer Company Limited (SFCL)
 
Sachpazis:Terzaghi Bearing Capacity Estimation in simple terms with Calculati...
Sachpazis:Terzaghi Bearing Capacity Estimation in simple terms with Calculati...Sachpazis:Terzaghi Bearing Capacity Estimation in simple terms with Calculati...
Sachpazis:Terzaghi Bearing Capacity Estimation in simple terms with Calculati...
 
Standard Reomte Control Interface - Neometrix
Standard Reomte Control Interface - NeometrixStandard Reomte Control Interface - Neometrix
Standard Reomte Control Interface - Neometrix
 
Railway Signalling Principles Edition 3.pdf
Railway Signalling Principles Edition 3.pdfRailway Signalling Principles Edition 3.pdf
Railway Signalling Principles Edition 3.pdf
 
weather web application report.pdf
weather web application report.pdfweather web application report.pdf
weather web application report.pdf
 
Heap Sort (SS).ppt FOR ENGINEERING GRADUATES, BCA, MCA, MTECH, BSC STUDENTS
Heap Sort (SS).ppt FOR ENGINEERING GRADUATES, BCA, MCA, MTECH, BSC STUDENTSHeap Sort (SS).ppt FOR ENGINEERING GRADUATES, BCA, MCA, MTECH, BSC STUDENTS
Heap Sort (SS).ppt FOR ENGINEERING GRADUATES, BCA, MCA, MTECH, BSC STUDENTS
 
DESIGN A COTTON SEED SEPARATION MACHINE.docx
DESIGN A COTTON SEED SEPARATION MACHINE.docxDESIGN A COTTON SEED SEPARATION MACHINE.docx
DESIGN A COTTON SEED SEPARATION MACHINE.docx
 
Building Electrical System Design & Installation
Building Electrical System Design & InstallationBuilding Electrical System Design & Installation
Building Electrical System Design & Installation
 
AP LAB PPT.pdf ap lab ppt no title specific
AP LAB PPT.pdf ap lab ppt no title specificAP LAB PPT.pdf ap lab ppt no title specific
AP LAB PPT.pdf ap lab ppt no title specific
 
Gen AI Study Jams _ For the GDSC Leads in India.pdf
Gen AI Study Jams _ For the GDSC Leads in India.pdfGen AI Study Jams _ For the GDSC Leads in India.pdf
Gen AI Study Jams _ For the GDSC Leads in India.pdf
 
Unbalanced Three Phase Systems and circuits.pptx
Unbalanced Three Phase Systems and circuits.pptxUnbalanced Three Phase Systems and circuits.pptx
Unbalanced Three Phase Systems and circuits.pptx
 
English lab ppt no titlespecENG PPTt.pdf
English lab ppt no titlespecENG PPTt.pdfEnglish lab ppt no titlespecENG PPTt.pdf
English lab ppt no titlespecENG PPTt.pdf
 
Investor-Presentation-Q1FY2024 investor presentation document.pptx
Investor-Presentation-Q1FY2024 investor presentation document.pptxInvestor-Presentation-Q1FY2024 investor presentation document.pptx
Investor-Presentation-Q1FY2024 investor presentation document.pptx
 
Final project report on grocery store management system..pdf
Final project report on grocery store management system..pdfFinal project report on grocery store management system..pdf
Final project report on grocery store management system..pdf
 
Nuclear Power Economics and Structuring 2024
Nuclear Power Economics and Structuring 2024Nuclear Power Economics and Structuring 2024
Nuclear Power Economics and Structuring 2024
 
Cosmetic shop management system project report.pdf
Cosmetic shop management system project report.pdfCosmetic shop management system project report.pdf
Cosmetic shop management system project report.pdf
 

Ch-5.0_Robot Technology - CIM.pptx

  • 1. Department of Mechanical Engineering P.S. Ujeniya Unit no 6 Unit title RT CAM - 2171903 ROBOTTECHNOLOGY
  • 2. INDUSTRIAL ROBOTS:  Automation and robotics are closely related technologies.  Automation is concerned with the use of mechanical, Electronics and computer based systems in the operation and control of production.  Examples of this technology include transfer lines, mechanized assembly machines, feedback control systems, NC machine tools and robots.  Accordingly, robotics is a form of industrial automation.
  • 3. AUTOMATION AND ROBOTICS:  There are three broad classes of industrial automation: 1. Fixed automation 2. Programmable automation 3. Flexible automation
  • 5.  Of the three types of automation, robotics coincides most closely with programmable automation.  An industrial robot is a general-purpose, programmable machine which possesses certain anthropomorphic, or humanlike, characteristics.  The most typical humanlike characteristic or present-day robots is their movable arms.  The robot can be programmed to move its arm through a sequence of motions in order to perform some useful task.  The programming feature allows robots to be used for a variety of different industrial operations, many of which involve the robot working together with other pieces of automated or semi automated equipments.  These operations include machine loading and unloading, spot welding and spray painting. RT
  • 6.  The “official” definition of an industrial robot is provided by the Robotics Industries Association (RIA), formerly the Robotics Institute of America (RIA):  “An industrial robot is a reprogrammable, multifunctional manipulator designed to move material, parts, tools, or special devices through variable programmed motions for the performance of a variety of tasks.”  This definition reinforces that industrial robots should be classified as a form of programmable automation.  While the robots themselves are examples of programmable automation, they are sometimes used in flexible automation and even fixed automation systems. RT
  • 7. ROBOT ANATOMY:  Robot anatomy is concerned with the physical construction of the body, arm and wrist of the machine.  Generally, robot body is attached to the base and the arm assembly is attached to the body.  At the end of the arm is the wrist.  The wrist consists of a number of components that allow it to be oriented in a variety of positions.  Relative movements between the various components of the body, arm and wrist are provided by a series of joints.  These joint movement usually involve either rotating or sliding motions.
  • 8.  The body, arm and wrist assembly is sometimes called the manipulator.  Attached to the robot’s wrist is a hand. The technical name for the hand is “End effector”.  The end effector is not considered as the part of the robot’s anatomy.  The arm and body joints of the manipulator are used to orient the end effector.
  • 9. CLASSIFICATION OF ROBOTS  The following is the classification of robots according to the Japanese Industrial Robot Association (JIRA): 1. Class 1: Manual Handling Device - A device with multiple degrees of freedom that is actuated by an operator. 2. Class 2: Fixed sequence Robot: - A device that performs the successive stages of a task according to a predetermined, unchanging method and is hard to modify. 3. Class 3: Variable-Sequence Robot: - Same as class 2, but easy to modify.
  • 10. 4. Class 4: Playback Robot: - A human operator performs the task manually by leading the robot, which records the motions for later playback. - The robot repeats the same motions according to the recorded information. 5. Class 5: Numerical Control Robot: - The operator supplies the robot with a movement program rather than teaching it the task manually. 6. Class 6: Intelligent Robot: - A robot with the means to understand its environment and the ability to successfully complete a task despite changes in the surrounding conditions under which it is to be performed.
  • 11. ADVANTAGES AND DISADVANTAGES OF ROBOT: Advantages:  Robotics and automation can, in many situations, increase productivity, safety, efficiency, quality and consistency of products.  Robots can work in hazardous environments without the need for life support, comfort, or concern about safety.  Robots needs no environmental comfort, such as lighting, air conditions, ventilation, and noise protection.  Robots work continuously without experiencing fatigue or boredom, do not get mad, do not have hangovers, and need no medical insurance or vacation.
  • 12.  Robots have repeatable precision at all times, unless something happens to them or unless they wear out.  Robots can be much more accurate than humans. Typical linear accuracies are a few thousands of an inch. New wafer- handling robots have micro inch accuracies.  Robots and their accessories and sensors can have capabilities beyond that of humans.  Robot can process multiple stimuli or tasks simultaneously. Humans can only process one active stimulus.  Robot replace human workers creating economic problems, such as lost salaries, and social problems, such as dissatisfaction and resentment among workers. ADVANTAGES AND DISADVANTAGES OF ROBOT:
  • 13. Disadvantages  Robots lack capability to respond in emergencies, unless the situation is predicted and the response is included in the system. Safety measures are needed to ensure that they do not injure operator and machines working with them. This includes: - Inappropriate or wrong responses - A lack of decision making power - A loss of power - Damage to the robot and other devices - Human injuries ADVANTAGES AND DISADVANTAGES OF ROBOT:
  • 14.  Robots, although superior in certain senses, have limited capabilities in - Degrees of freedom - Dexterity - Sensors - Vision systems - Real-time response  Robots are costly, due to - Initial cost of equipment - Installation costs - Need for training - Need for programming
  • 16. 1. Manipulator or Rover: - This is the main body of the robot and consists of the links, the joints, and other structural elements of the robot. 2. End effector: - This is the part that is connected to the last joint (hand) of a manipulator, which generally handles objects, makes connection to other machines, or performs the required task. 3. Actuators: - Actuators are the “muscles” of the manipulators. Common types of actuators are servomotors, stepper motors, pneumatic cylinders and hydraulic cylinders. ROBOT COMPONENTS:
  • 17. 4. Sensors: - Sensors are used to collect information about the internal state of the robot or to communicate with the outside environment. - Robots are equipped with external sensory devices such as a vision system, touch and tactile sensors, speech synthesizers etc. which enable the robot to communicate with the outside world. 5. Controller - The controller is rather similar to cerebellum and although it does not have the power of brain, it still controls motion. - The controller receives its data from the computer, controls the motion of the actuators and coordinates the motions with the sensory feedback information. ROBOT COMPONENTS:
  • 18. 6. Processor: - The processor is the brain of robot. - It calculates the motions of the robot’s joints, determines how much and how fast each joint must move to achieve the desired location and speeds, and oversees the coordinated actions of the controller and sensors. - Processor is generally a computer which works like all other computers, but is dedicated to a single purpose. ROBOT COMPONENTS:
  • 19. 7. Software: - There are perhaps three groups of software that are used in robot. - One is operating system, which operates computer. - The second is the robotic software, which calculates the necessary motions of each joint based on the kinematic equations of the robot. This information is sent to the controller. - The third group is the collection of routines and application programs that are developed in order to use the peripheral devices of the robots, such as vision routines, or to perform specific tasks. ROBOT COMPONENTS:
  • 20. ROBOT PHYSICAL CONFIGURATIONS:  Industrial robots are available in a wide variety of sizes, shapes and physical configurations.  The vast majority of today’s commercially available robots possess one of the four basic configurations: 1. Polar configuration 2. Cylindrical configuration 3. Cartesian coordinate configuration 4. Jointed-arm configuration
  • 21. 1. POLAR CONFIGURATION:  The polar configuration uses a telescoping arm that can be raised or lowered about a horizontal pivot.  The pivot is mounted on a rotating base.  These various joints provide the robot with the capability to move its arm within a spherical space, and hence the name “spherical coordinate robot” is sometimes applied to this type.  A number of commercial robots posses the polar configuration.  Examples – - Unimate 2000 series - MAKER 110
  • 22. 2. CYLINDRICAL CONFIGURATION:  The cylindrical configuration, uses a vertical column and a slide that can be moved up and down along the column.  The robot arm is attached to the slide so that it can be moved radially with respect to the column.  By rotating the column, the robot is capable of achieving a work space that approximates a cylinder.
  • 23. 3. CARTESIAN COORDINATE CONFIGURATION:  The Cartesian coordinate robot, uses three perpendicular slides to construct the x, y and z axes.  Other name are sometimes applied to this configuration, including ‘xyz robot’ and ‘rectilinear robot’.  By moving the three slides relative to one another, the robot is capable of operating within a rectangular work envelope.
  • 24.  Examples- IBM RS-1 robot (Model 7565)  The RS-1, because of its appearance and construction, is occasionally referred to as a “box” configuration.  “Gantry” robot is another name used for Cartesian robot that are generally large and possess the appearance of a gantry type crane.
  • 25. 4. JOINTED ARM CONFIGURATION:  This configuration is similar to that of human arm.  It consists of two straight components, corresponding to the human forearm and upper arm, mounted on a vertical pedestal.  These components are connected by two rotary joints corresponding to the shoulder and elbow.  A wrist is attached to the end of the forearm, thus providing several additional joints.
  • 26.  A special version of the jointed arm robot is the SCARA, whose shoulder and elbow joints rotate about vertical axes.  SCARA stands for - ‘Selective Compliance Assembly Robot Arm’.  This configuration provides substantial rigidity for the robot in the vertical direction, but compliance in the horizontal plane.  This makes it ideal for many assembly tasks.
  • 27. COMPARISION OF PHYSICAL CONFIGURATIONS:  There are relative advantages and disadvantages to the four basic robot anatomies simply because of their geometries.  In terms of repeatability of motion (the capability to move to a taught point in space with minimum error), the box-frame cartesian robot probably possesses the advantage because of its inherently rigid structure.  In terms of reach (ability of the robot to extend its arm significantly beyond its base), the polar and jointed are configuration have the advantage.  The cylindrical configuration and the gantry xyz robot can be designed for high-rigidity and load- carrying capacity.  For machine-loading applications, the ability of the robot to reach into a small opening without interference with the sides of the opening is important. The polar configuration and the cylindrical configuration possess a natural geometric advantage in terms of this capability.
  • 28. ROBOTIC POWER SOURCES:  Commercially available industrial robots are powered by one of the three types of drive systems. 1. Hydraulic drive 2. Electric drive 3. Pneumatic drive  Hydraulic drive and electric drive are the two main types of drives used on more sophisticated robots.
  • 29. HYDRAULIC DRIVE:  Hydraulic drive is generally associated with larger robots, such as the Unimate 2000 series.  The usual advantage of the hydraulic drive system are that it provides the robot with greater speed and strength.  The disadvantages of the hydraulic drive system are that it typically adds to the floor space required by the robot, and that a hydraulic system is inclined to leak oil which is a nuisance.  Hydraulic drive systems can be designed to actuate either rotational joints or linear joints.  Rotary vane actuators can be used to accomplish linear motion.
  • 30. ELECTRIC DRIVE:  Electric drive systems do not generally provide as much speed or power as hydraulic system.  However, the accuracy and repeatability of electric drive robots are usually better.  Consequently, electric robots tend to be smaller, requiring less floor space, and their applications tend toward more precise work such as assembly.  The MAKER 110 is an example of an electric drive robot that is consistent with these tendencies.  Electric drive robots are actuated by dc stepping motors or dc servomotors. These motors are ideally suited to the actuation of rotational joints through appropriate drive train and gear systems.  Electric motors can also be used to actuate linear joints (telescoping arms) by means of pulley systems or other translational mechanisms.
  • 31.  The economics of the two types of drive systems are also a factor in the decision to utilize hydraulic drive on large robots and electric drive on smaller robots.  It turns out that the cost of an electric motor is much more proportional to its size, whereas the cost of a hydraulic drive system is somewhat less dependent on its size.  As shown in the figure, there is a hypothetical break-even point, below which it is advantageous to use electric drive and above which it is appropriate to use hydraulic drive.  So, there is a trend in the design of industrial robots toward all electric drives, and away from hydraulic robots.
  • 32. Cost vs. size for electric drive and hydraulic drive
  • 33. PNEUMATIC DRIVE:  Pneumatic drive is generally reserved for smaller robots that possess fewer degrees of freedom (two- to four- joint motions).  These robots are often limited to simple “pick and place” operations with fast cycles.  Pneumatic power can be readily adapted to the actuation of piston devices to provide translational movement of sliding joints.  It can also be used to operate rotary actuators for rotational joints.
  • 34. TECHNICAL FEATURES: 1. Work volume 2. Precision of movement a) Spatial resolution b) Accuracy c) Repeatability 3. Speed of movement 4. Weight carrying capacity (pay load)
  • 35. WORK VOLUME:  The term "work volume" refers to the space within which the robot can operate.  To be technically precise, the work volume is the spatial region within which the end of the robot's wrist can be manipulated.  Robot manufacturers have adopted the policy of defining the work volume in terms of the wrist end, with no hand or tool attached.  The work volume of an industrial robot is determined by its physical configuration, size and the limits of its arm and joint manipulations.
  • 36.  The work volume of a Cartesian coordinate robot will be rectangular.  The work volume of a cylindrical coordinate robot will be cylindrical.  A polar coordinate configuration will generate a work volume which is a partial sphere.  The work volume of a jointed arm robot will be somewhat irregular, the outer reaches generally resembling a partial sphere. WORK VOLUME:
  • 37. The work volumes for various anatomies (a) polar (b) cylindrical (c) cartesian
  • 38. PRECISION OF MOVEMENT:  The precision with which the robot can move the end of its wrist is a critical consideration in most applications.  In robotics, precision of movement is a complex issue, and it is described as three attributes: 1. Spatial resolution 2. Accuracy 3. Repeatability  These attributes are generally interpreted in terms of the wrist end with no end effector attached and with the arm fully extended.
  • 39. SPATIAL RESOLUTION:  The term "spatial resolution" refers to the smallest increment of motion at the wrist end that can be controlled by the robot.  This is determined largely by the robot's control resolution, which depends on its position control system and/or its feedback measurement system.  In addition, mechanical inaccuracies in the robot's joints would tend to degrade its ability to position its arm.  The spatial resolution is the sum of the control resolution plus these mechanical inaccuracies.
  • 40.  The factor determining control resolution are the range of movement of the arm and the bit storage capacity in the control memory for that movement.  The arm movement must be divided into its basic motions or degrees of freedom, and the resolution of each degree of freedom is figured separately. Then the total control resolution is the vector sum of each component.
  • 41. ACCURACY:  The accuracy of the robot refers to its capability to position its wrist end (or a tool attached to the wrist) at a given target point within its work volume.  Accuracy is closely related to spatial resolution, since the robot's ability to reach a particular point in space depends on its ability to divide its joint movements into small increments.  According to this relation, the accuracy of the robot would be one half the distance between the two adjacent resolution points.  The robot's accuracy is also affected by mechanical inaccuracies, such as deflection of its components, gear inaccuracies, and so worth.
  • 42.
  • 43. REPEATABILITY:  This refers to the robot's ability to position its wrist end (or tool) back to a point in space that was previously taught.  Repeatability is different from accuracy.  The robot was initially programmed to move the wrist end to the target point T. Because it is limited by its accuracy, the robot was only capable of achieving point A. The distance between points A and T is the accuracy.  Later, the robot is instructed to return to this previously programmed point A. However, because it is limited by it repeatability, it is only capable of moving to point R.  The distance between points R and A is a measure of the robot's repeatability.  As the robot is instructed to return to the same position in subsequent work cycles, it will not always return to point R, but instead will form a cluster of positions about point A.
  • 44. Illustration of Repeatabili ty versus accuracy  Repeatability errors form a random variable.  In general, repeatability will be better than accuracy.  Mechanical inaccuracies in the robot‘s arm and wrist components are principal sources of repeatability errors.
  • 45. END EFFECTORS:  In the terminology of robotics, an end effector can be defined as a device which is attached to the robot's wrist to perform a specific task.  The task might be work part handling, spot welding, spray painting, or any of a great variety of other functions.  The end effector is the special-purpose tooling which enables the robot to perform a particular job.  It is usually custom engineered for that job, either by the company that owns the robot or by the company that sold the robot.  Most robot manufacturers have engineering groups which design and fabricate end effectors or provide advice to their customers on end effector design.  For purposes of organization, we will divide the various types of end effectors into two categories:  grippers and tools
  • 46. GRIPPERS:  Grippers are used to hold either work parts (in pick-and-place operations, machine loading, or assembly work) or tools.  There are numerous alternative ways in which the gripper can be designed. The most appropriate design depends on the work part or substance being handled. The following is a list of the most common grasping methods used in robot grippers : - Mechanical grippers, where friction or the physical configuration of the gripper retains the object - Suction cups (also called vacuum cups), used for flat objects Magnetized gripper devices, used for ferrous objects - Hooks, used to lift parts off conveyors - Scoops or ladles, used for fluids, powders, pellets, or granular substances
  • 47. Sample gripper designs (a) pivot action gripper; (b) slide action gripper; (c) double gripper-pivot action mechanism; (d) vacuum-operated hand GRIPPERS:
  • 48. OTHER TYPES OF GRIPPERS: 1. Vacuum cups 2. Magnetic grippers 3. Adhesive grippers 4. Hooks, scoops and other miscellaneous devices.
  • 50.
  • 51. TOOLS AS END EFFECTOR:  There are a limited number of applications in which a gripper is used to grasp tool and use it during the work cycle.  In most applications where the robot manipulates a tool during the cycle, the tool is fastened directly to the robot wrist becomes the end effector.  A few examples of tools used with robots are the following: - Spot welding gun - Arc welding tools (and wire-feed mechanisms) - Spray painting gun - Drilling spindle - Routers, grinders, wire brushes - Heating torches
  • 52. WORK CELL CONTROL:  Industrial robots usually work with other things: processing equipment, work part conveyors, tools, and perhaps, human operators.  Some of the activities occur sequentially, while others take place simultaneously.  To make certain that the various activities are coordinated and occur in the proper sequence, a device called the work cell controller is used (another name for this is workstation controller).  The work cell controller usually resides within the robot and has overall responsibility for regulating the activities of the work cell components.
  • 53.
  • 54. SENSORS:  Sensors are used to collect information about the internal state of the robot or to communicate with the outside environment.  In a robot, as the links and joints move, sensors such as potentiometers, encoders and resolvers send signals to the controller that allow it to determine where each joint is.  The sensors may be similar in function to that of humans, such as vision, touch, and smell.  In some cases, the sensors may be something humans do not have, such as radioactive sensor.
  • 55. SENSOR CHARACTERISTICS:  The characteristics of sensors determine the performance, economy, ease of application, and applicability. 1. Accuracy: Accuracy is defined as how close the output of sensor is to the expected value. 2. Repeatability: If the sensor’s output is measured a number of times in response to the same input, the output may be different each time. Repeatability is a measure of how varied the different outputs are relative to each other. 3. Range: Range is the difference between the smallest and the largest outputs the sensor can produce, or the difference between the smallest and the largest inputs with which it can operate properly.
  • 56. 4. Response time (Speed of Response):  Response time is the time that a sensor’s output requires to reach a certain percentage of the total change. It is usually expressed in percentage of total change, such as 95%.  It is also defined as the time required to observe the change in output as a result of a change in input. 5. Sensitivity: The sensitivity is the ratio of a change in output in response to a change in input. Highly sensitive sensors will show larger fluctuations in output as a result of fluctuations in input, including noise. 6. Linearity: Linearity represents the relationship between input variations and output variations. Almost all the devices in nature are somewhat nonlinear, with varying degrees of nonlinearity. Certain devices can be assumed to be linear within a certain range of operation. SENSOR CHARACTERISTICS:
  • 57. 7. Interfacing: The sensor should be easy to interface with other devices such as microprocessors and controller. 8. Reliability: Reliability is the ratio of how many time a system operates properly divided by how many times it is tries. 9. Frequency response: The larger the range of the frequency response, the better the ability of the system to respond to varying input. 10. Cost and Ease of Operation: The cost of purchase, installation and operation of sensor should be as low as possible. The installation and operation of sensor should be simple and easy. 11. Size and Weight: The size and weight of the sensor should be as small as possible. SENSOR CHARACTERISTICS:
  • 58. TYPES OF SENSORS: SENSORS TECTILE OR CONTACT SENSORS TOUCH SENSORS FORCE SENSORS POSITION OR DISPLACEMENT SENSORS NON-CONTACT SENSORS PROXIMITIY OR RANGE SENSORS ROBOT VISION SYSTEMS VOICE SENSORS
  • 59. TACTILE SENSORS:  Tactile sensors are divided into following categories. 1. Touch sensors 2. Force sensors 3. Position and displacement sensors Touch sensors:  Touch sensors are devices that send a signal when physical contact has been made.  The simplest form of touch sensor is microswitch, which either turns on or off as contact is made.  These sensors indicated and respond to the presence or absence of an object. They provide the binary output signals.
  • 60. Force Sensors:  Force sensors are used to measure the magnitude of contact force.  These sensors are analog type sensors in which the output signal is proportional to local force.  Examples- Piezoelectric sensors, force sensing resistors, strain gauges etc. Position and Displacement sensors:  Position sensors are used to measure displacement, both rotary and linear, as well as movements.  In many cases the position information may also be used to calculate velocities.  Examples- Potentiometers, encoders, linear variable differential transformers (LVDT), resolvers etc.
  • 61. PROXIMITY SENSORS:  Proximity sensors are used to determine that an object is close to another object before the contact is made.  This noncontact sensing is useful in many situation, from measuring the speed of a rotor to navigating a robot.  Examples- Magnetic and eddy current sensors, optical, ultrasonic inductive and capacitive. VISION SENSORS:  Computerized visions systems will be an important technology in future automated factories.  Robot vision is made possible by means of a video camera, a sufficient light source, and a computer programmed to process image data.  The camera is mounted either on the robot or in a fixed position above the robot so that its field of vision includes the robot's work volume.
  • 62.  The computer software enables the vision system to sense the presence of an object and its position and orientation.  Vision capability would enable the robot to carry out the following kinds of operations: - Retrieve parts which are randomly oriented on a conveyor. - Recognize particular parts which are intermixed with other objects. - Perform visual inspection tasks. - Perform assembly operations which require alignment.  All of these operations have been accomplished in research laboratories. It is merely a matter of time and economics before vision sensors become a common feature in robot applications.
  • 63. VOICE SENSORS:  Another area of robotics research is voice sensing or voice programming.  Voice programming can be defined as the oral communication of commands to the robot or other machine.  The robot controller is equipped with a speech recognition system which analyzes the voice input and compares it with a set of stored word patterns.  When a match is found between the input and the stored vocabulary word, the robot performs some action which corresponds to that word.  Voice sensors would be useful in robot programming to speed up the programming procedure, just as it does in NC programming.  It would also be beneficial in especially hazardous working environments for performing unique operations such as maintenance and repair work.
  • 64.
  • 65.
  • 66. ACTUATORS:  Actuators are the muscles of robots.  If links and joints are considered as the skeleton of the robot, the actuators, act as, muscles, which move or rotate the links to change the configuration of robots.  The actuators must have enough power to accelerate and decelerate the links and to carry the loads, yet be light, economical, accurate, responsive, reliable and easy to maintain.
  • 67. Types of Actuators:  Mechanical actuators  Electric motors - Servomotors - Stepper motors - Direct drive electric motors  Hydraulic actuators  Pneumatic actuators  Shape memory metal actuators  Magnetostrictive actuators
  • 68. MECHANICAL ACTUATORS:  Mechanical actuators are classified into two types: 1. Linear Mechanical actuators 2. Rotary Mechanical actuators Linear Mechanical Actuators:  Linear mechanical actuators are used to actuate the linear manipulator joints of the robot.  Examples – Rack and pinion - Recirculating ball screws Rotary Mechanical Actuators:  Examples – Timing belts - Gear pairs - Harmonic drives
  • 69. ELECTRIC MOTORS: DC Motors:  DC motors are common in industry and are reliable and relatively powerful. AC Motors:  Electric AC motors are similar to DC motor, except that the rotor is permanent magnet, the stator houses the winding. Direct Drive Electric Motors:  These motors are designed to deliver a very large torque at very low speeds and with very high resolution.  These motors are intended to be used directly with a joint without any gear reduction.  Direct drive motors are still very expensive and very heavy, but have impressive characteristics.
  • 70. Servomotors:  In a servomotor, by varying current (or corresponding voltage) the speed torque balance can be maintained.  A servomotor is DC, AC, brushless or even stepper, motor with feedback that can be controlled to move at a desired speed for a desired angle of rotation. Stepper Motors:  Stepper motors are versatile, long- lasting, simple motors that can be used in many applications.  In most applications, the stepper motors are used without feedback.
  • 71. HYDRAULIC ACTUATORS:  Hydraulic actuators offer a high power to weight ratio, large forces at low speeds, compatibility with microprocessor and electronic controls and can be used in extreme hazardous environments.  A hydraulic system generally consists of the following parts: 1. Hydraulic linear or rotary cylinders and rams 2. A hydraulic pump 3. Electric motors 4. Cooling system 5. Reservoir 6. Valves and connecting hoses 7. Sensors
  • 72. PNEUMATIC ACTUATORS:  A source of pressurized air is used to power and drive linear or rotary cylinders, controlled by manual or electrically controlled solenoid valves.  Pneumatic actuators are of linear or rotary type.  A linear pneumatic actuators are the single acting or double acting pneumatic cylinders used to actuate the linear joints of the robots.  The cylinders are operated by compressed air at about 35 to 70 bar pressure.  High pressure compressed air runs the pneumatic motors. The torque developed by pneumatic motor actuates the rotary joints.
  • 73. ROBOT APPLICATIONS:  General Application Characteristics 1. Hazardous or uncomfortable working conditions 2. Repetitive tasks 3. Difficult handling 4. Multishift operation
  • 74. Application Areas for Industrial Robots: 1. Material transfer 2. Machine loading 3. Welding 4. Spray coating 5. Processing operations 6. Assembly 7. Inspection
  • 75. 1. MATERIAL TRANSFER  Simple pick and place operations  Transfer of workparts from one conveyer to another conveyer  Palletizing operations, in which the robot takes parts from a conveyor and loads them onto pallet in required pattern and sequence  Stacking operation  Loading parts from a conveyor into cartons or boxes  Depalletizing operations, in which the robot takes parts which are arranged on a pallet and loads them onto a conveyor
  • 76. 2. MACHINE LOADING  Machine loading applications are material handling operations in which the robot is required to supply a production machine with raw work parts and/or to unload the finish parts form the machine.  Machine loading is distinguish form a material transfer operation by the fact that the robot works directly with the processing equipments.  Production operations in which robot have been successfully applied to perform the machine loading and unloading function includes: - Die casting - Injection (plastic) molidng - Hot forging - Upsetting or upset forging - Stamping press operations - Machining operations such as turning and milling
  • 77. 3. WELDING:  Spot welding  Arc welding
  • 78. 4. SPRAY PAINTING  Spray painting process poses certain health hazards to the human operator. These are - fumes and mist from the spraying operation - noise from the spray nozzles - fire hazard - possible cancer dangers  For these and other reasons, specialized industrial robots are being used more and more frequently to perform spray painting operations.  Advantages of using robot in this applications are: - safety - Coating consistency - Lower material usage - Less energy used - Greater productivity
  • 79. 5. PROCESSING OPERATIONS:  Drilling  Riveting  Grinding  Polishing  Deburring  Wire brushing  Waterjet cutting
  • 80. 6. ASSEMBLY:  Adaptable-programmable assembly system (APAS)  PUMA (Programmable Universal Machine for Assembly) 7. INSPECTION:  Robots equipped with mechanical probes, optical sensing capabilities, or other measuring devices can be programmed to perform dimensional checking and other forms of inspection operations.
  • 81. ECONOMIC ANALYSIS FOR ROBOTICS  The economic analysis for any proposed robot project is of considerable importance in most companies because management usually decides whether to install the project on the basis of this analysis.  To perform the economic analysis of a proposed robot project, certain basic information is needed about the project.  This information includes- - the type of project being considered - the cost of the robot installation - the production cycle time - savings and benefits resulting from the project
  • 82. Cost data required for the analysis:  The cost data required to perform the economic analysis of a robot project divide into two types: 1. Investment costs: - Robot purchase cost - Planning and design cost - installation cost - Special tooling - Miscellaneous costs 2. Operating costs: - Direct labor cost - Indirect labor cost - Maintenance - Utilities - Training
  • 83. INTERFACING A VISION SYSTEM WITH A ROBOT:  Machine vision is concerned with the sensing of vision data and its interpretation by computer.  The typical vision system consists of the camera and digitizing hardware, a digital computer and hardware and software necessary to interface them with the robot.  This interface hardware and software is often referred to as preprocessor.  The operation of the vision system consists of three functions: 1. Sensing and digitizing image data 2. Image processing and analysis 3. Application  Current typical application of machine vision with robot are for inspection task in high speed production line to accept or reject parts made on the line. Unacceptable parts are ejected from the line by some mechanical device that is communicating with the vision system.
  • 84. INTELLIGENT ROBOTS:  Artificial Intelligence efforts aim at developing systems that appear to behave intelligently. Often this is described as developing machines that “think”.  Typically this work is carried out as a branch of computer science, although it also contains element of psychology and mathematics.  One of the problems involved with vision systems is the representation of data within the system.  Rather than store pictures of the parts within the vision systems memory, certain features about the objects are stored, such as perimeter, area, number of holes, and so on.
  • 85.  As the system become more complex and begin to be able to deal in crowded three-dimensional environments it will require greater intelligence on the part of the vision system.  Techniques have been developed which allow vision systems to recognize specific types of objects even when mixed together.  These systems rely heavily on artificial intelligent methods to increase their processing speed.