Casting, forming, forging, extruding and molding are primary machining. Material removal and change of shape, drilling, grooving, dimensional corrections are some very special specific techniques, which are used in specialist workshops or machines are suppose to be the secondary machining, Turning, milling, drilling grinding, shaping are some of the secondary machining process. Chuck, face plate, vice, jigs, fixtures special centers are the work holding devices. Vernier calipers, micrometer, compactors, depth micrometers are some of the measuring tools using for secondary machining Turning, threading grooving, parting tools, milling cutters, taps drill bits, etc are cutting tools using for secondary machining techniques. Cutting speed, Speed, Feed rate, etc are the cutting parameters Inspections, verification, comparison, are the quality control methods in this kinematics. Assessments of health and safety measures are yet another kinematics in this technique.
kinematic is actually the study of motion with out discussing the cause of motion however it may be mechanical
Rotational kinematics is the same as linear kinematics but with objects in rotation. All of the linear kinematic equations that you learn for velocity and acceleration can be applied to rotational kinematics except that the greek w (omega) is used for velocity and the greek a (alpha) is used for acceleration.
Genetic engineering techniques have been applied in numerous fields including agriculture. One of the best-known applications of genetic engineering in agriculture is genetically modified organisms.
Restriction enzymes or endonucleases are like cutting enzymes fro DNA These are used to cut nucleotides at particular sites These have imp use in gene cloning,gene mapping,gene sequencing then applied techniques such as southern blotting These are extracted from bacteria's
the term binary fission is best applied to
A solid will maintain its shape when force is applied to it.
Robert Kraus has written: 'Grundlagen des systematischen Getriebeaufbaus' -- subject(s): Applied Mechanics, Kinematics of Machinery, Machinery, Kinematics of, Mechanics, Applied 'Getriebelehre' -- subject(s): Applied Mechanics, Kinematics of Machinery, Machinery, Kinematics of, Mechanics, Applied
Rotational kinematics is the same as linear kinematics but with objects in rotation. All of the linear kinematic equations that you learn for velocity and acceleration can be applied to rotational kinematics except that the greek w (omega) is used for velocity and the greek a (alpha) is used for acceleration.
D C. Tao has written: 'Fundamentals of applied kinematics'
John Harland Billings has written: 'Mechanics and design of machines' -- subject(s): Machine design, Mechanical engineering 'Applied kinematics for students and mechanical designers' -- subject(s): Kinematics of Machinery
A voltage is never applied to the secondary It can be used as a source but hen it becomes the primary by definition
Applied biochemistry is that part of the field in which the knowledge and techniques are applied to the real world.
Given a Transformer with 110vac at 1 amp applied to the primary with 1000 turns and the secondary of 500 turns what is the voltage current and power of the secondary?
In ordinary machining we use harder tool to work on workpiece , this limitation is overcome by unconventional machining. unconventional machining is directly using some sort of indirect energy for machining. Example : sparks, lasers, heat , chemicals etc.. applied in EDM ,laser cutting machines...etc
In years of reading research on autism, I have not encountered the term "applied autism", but the two words could appear together, such as "applied autism teaching techniques".
In years of reading research on autism, I have not encountered the term "applied autism", but the two words could appear together, such as "applied autism teaching techniques".
1. the branch of mechanics that deals with pure motion, without reference to the masses or forces involved in it. 2. Also called applied kinematics. the theory of mechanical contrivance for converting one kind of motion into another.
Non conventional Machining is a recent development in machining techniques. It is based on unconventional machining techniques using Laser beam, Electron beam, Electric arc etc. Conventional machining involves the direct contact of tool and work -piece, whereas unconventional machining does not require the direct contact of tool and wor piece. Conventional machining has many disadvantages like tool wear which are not present in Non-conventional machining. Examples : Electric arc machining, Laser cutting , electro discharge machining, plasma cutting etc Advantages of Non-conventional machining: 1) High accuracy and surface finish 2) no direct contact of tool and workpiece, so there is less/no wear 3) tool life is more 4 ) quieter operation Disadvantages of non-conventional machining: 1) high cost 2) complex set-up 3) skilled operator required