machine design

design for manufacturability

design for manufacturability, design for assembly or design for production

Gen Mgt

the process of designing a product for best-fit with the manufacturing system of an organization in order to reduce the problems of bringing a product to market. Design for manufacturability is a team approach to manufacturing that pairs those responsible for the design of a product with those who build it. The manufacturing issues that need to be taken into account in the design process may include using the minimum number of parts, selecting appropriate materials, ease of assembly, and minimizing the number of machine set-ups. Design for manufacturability is one of the elements of concurrent engineering and is sometimes used as a synonym for it.

Also known as engineering for excellence, manufacturing for excellence, producibility engineering

design for assembly

design for manufacturability, design for assembly or design for production

Gen Mgt

the process of designing a product for best-fit with the manufacturing system of an organization in order to reduce the problems of bringing a product to market. Design for manufacturability is a team approach to manufacturing that pairs those responsible for the design of a product with those who build it. The manufacturing issues that need to be taken into account in the design process may include using the minimum number of parts, selecting appropriate materials, ease of assembly, and minimizing the number of machine set-ups. Design for manufacturability is one of the elements of concurrent engineering and is sometimes used as a synonym for it.

Also known as engineering for excellence, manufacturing for excellence, producibility engineering

design for production

design for manufacturability, design for assembly or design for production

Gen Mgt

the process of designing a product for best-fit with the manufacturing system of an organization in order to reduce the problems of bringing a product to market. Design for manufacturability is a team approach to manufacturing that pairs those responsible for the design of a product with those who build it. The manufacturing issues that need to be taken into account in the design process may include using the minimum number of parts, selecting appropriate materials, ease of assembly, and minimizing the number of machine set-ups. Design for manufacturability is one of the elements of concurrent engineering and is sometimes used as a synonym for it.

Also known as engineering for excellence, manufacturing for excellence, producibility engineering

design

تَصْمِيم \ design: a drawing from which sth. can be made; a plan: He showed me the designs for the new hotel. determination: being decided; firm intention: the will to succeed: She is a woman of great determination who always gets what she wants. layout: sth. that is laid out; a neat arrangement (of a piece of written work, etc.). plan: a drawing of a building or machine, showing how it will be (or has been) made.

machine-tool design

конструирование катода-инструмента ( для электрохимической размерной обработки)

Jacquard Machine

JACQUARD MACHINE

The jacquard machine is an essential addition to looms intended for weaving ornamental designs that are beyond the scope of stave -work. The machine is made in many forms and sizes for different branches of the weaving industry, but its characteristic feature is that it furnishes the means whereby every individual thread in a design may weave differently from all the others. This permits the delineation of all forms and shapes and the fineness of the detail is only limited by the texture, e.g., the number of ends and picks per inch. The action of the jacquard machine is communicated to the warp threads through a system of cords known variously as the harness mounting and jacquard harness. Actually, loom harness ante-dated the jacquard machine by many centuries, and many draw loom harnesses were much more complicated than modern jacquard harnesses. An essential feature of a jacquard is that each hook in the machine can be lifted at will independently of the others. The selection of which hooks shall lift and which shall be left down is made by the designer, by painting marks on squared paper to indicate the hooks that must be lifted on each pick. In cutting the pattern cards, a hole is cut for every mark or filled square on the design paper, and a blank is left for every empty square on the paper. Assuming that each pattern card represents one pick of weft, when the card is pressed against the needles of the jacquard, the blanks push the unwanted needles and hooks out of the path of the lifting griffe; the holes allow the needles to pass through and thus remain stationary, so that the corresponding hooks remain in the path of the lifting griffe and cause the corresponding warp threads to be lifted. Jacquard: Single-lift, single-cylinder - In this machine there is only one griffe which lifts on every pick, and only one pattern cylinder, which strikes every pick. This restricts the speed at which the loom can be operated. Jacquard: Double-lift, single-cylinder - This is the machine in most common use for ordinary jacquard work. There are two lifting griffes and twice as many hooks as in a single-lift machine, but only the same number of needles and one card cylinder. The shed formed is of the semi-open type, which causes less movement of the warp threads, as any threads which require to be up for two or more picks in succession are arrested in their fall and taken up again. Double-lift jacquards give a greatly increased loom production as compared with single-lift machines, as they permit the speed of the loom to be increased to about 180 picks per minute for narrow looms, as compared with 120 to 140 picks per minute for single-lift jacquards. Jacquard: Double-lift, double-cylinder - In this machine there are two sets of hooks and needles, two lifting griffes and two card cylinders, odd picks in one set of cards and even picks in the other set. This permits maximum loom speed, it prolongs the life of the pattern cards, but is open to the serious drawback that spoiled cloth is caused whenever the two card cylinders get out of correct rotation. Jacquard: Cross Border - Fabrics with borders, such as tablecloths, bed quilts, etc., are woven with jacquards with two griffes, two sets of hooks and two card cylinders. The cards for weaving the border are laced together and weave on one cylinder, while the centre cards are on the other cylinder. The loom weaves at the speed of a single-cylinder, single-lift machine, and the change from the border to the centre cards can be made by hand or automatically

Co-design Finite State Machine

Computers: CFSM

Experimental Design Bureau of Machine Building

Chemical weapons: OKBM

Man-Machine Integration Design and Analysis System

Military: MIDAS

Special Machine Building Design Bureau

Military: SMBDB

engineering design machine

Engineering: EDM

crtanje i projektovanje elemenata mašina

• machine design

crtanje i projektovanje elemenata mašina

• machine design

конструкция машины

machine design

конструкция на машина

machine design

machine designs

автоматизированное проектирование

1) General subject: Computer-Assisted Design (CAD)

2) Engineering: automated engineering design, computer-aided design, computer-assisted engineering

3) Mathematics: automated, automatic, computer-aided, computer-based, computer-based design, design, or computer-assisted

4) Economy: automated designing

5) Architecture: computer-aided designing (CAD)

6) Telecommunications: computer aided design

7) Electronics: computer-assisted design

8) Information technology: automatized design, computer design, computer-aided design engineering, computer-aided drawing, man-machine design

9) Oil: computer-aided design (cad), design augmented by computer

10) Mechanics: cad-to-part approach, computer-integrated design

11) Business: CAD (computer-aided design), computer-aided design (CAD)

12) Household appliances: automated design

13) Sakhalin energy glossary: CAD computer-aided design, computer-assisted drafting

14) Microelectronics: computer-aided engineering

15) Automation: automated (design) engineering, automated construction, data-driven design

16) Makarov: machine design

автоматизированное проектирование

1. man-machine design

методология проектирования — design techniques

поэтажное проектирование — step-by-step design

предусматривать при проектировании — design in

проектирование конструкций — structural design

структурное проектирование — structured design

2. CAD

автоматизированное проектирование узлов — low-level cad work

3. computer aided design

проектирование структуры данных — data design

инженерное проектирование — engineering design

градостроительное проектирование — urban design

машинное проектирование — computer-aided design

проектирование бетонной смеси — concrete design

4. computer-aided design

норма проектирования — design code

цикл проектирования — design cycle

этап проектирования — design stage

данные проектирования — design data

нормы проектирования — design rules

conception

conception [kɔ̃sεpsjɔ̃]

feminine noun

   a. [d'enfant, projet] conception ; [de produit] design

• conception assistée par ordinateur computer-aided design

   b. ( = idée) idea ; ( = réalisation) creation

* * *

kɔ̃sɛpsjɔ̃

nom féminin

1) Biologie conception

2) ( formulation d'idée) conception

3) ( élaboration de la forme) design

au stade de la conception — at the design stage

4) ( idée) idea; ( façon de voir) conception

* * *

kɔ̃sɛpsjɔ̃ nf

conception, [machine] design

* * *

conception nf

1 Biol conception;

2 ( formulation d'idée) conception; la conception de l'œuvre a été lente it took a long time to conceive the work;

3 ( élaboration de la forme) design; au stade de la conception at the design stage; voiture d'une conception révolutionnaire car with a revolutionary design;

4 ( idée) idea; ( façon de voir) conception; elle a une conception bizarre de la fidélité she has a pretty odd conception ou idea of fidelity; ils ont une conception différente du mariage they don't share the same views on marriage, they have a different conception of marriage.

Composés

conception assistée par ordinateur, CAO computer-aided design, CAD; conception et fabrication assistées par ordinateur, CFAO CAD-CAM; conception de programmes assistée par ordinateur, CPAO computer-aided software engineering, CASE.

[kɔ̃sɛpsjɔ̃] nom féminin

1. [notion] idea, concept, notion

elle a une conception originale de la vie she has an original way of looking at life

2. (littéraire) [compréhension] understanding

3. BIOLOGIE conception

4. [élaboration - généralement] design ; [ - par une entreprise] product design

produit de conception française French-designed product

un ventilateur d'une conception toute nouvelle a fan with an entirely new design

5. INFORMATIQUE

conception assistée par ordinateur computer-aided design

conception et fabrication assistées par ordinateur computer-aided manufacturing

конструкция машины

1) Engineering: vehicle structure

2) Railway term: machine design

3) Economy: design of a machine

Hopkinson, John

SUBJECT AREA: Electricity, Electronics and information technology, Public utilities

[br]

b. 27 July 1849 Manchester, England

d. 27 August 1898 Petite Dent de Veisivi, Switzerland

[br]

English mathematician and electrical engineer who laid the foundations of electrical machine design.

[br]

After attending Owens College, Manchester, Hopkinson was admitted to Trinity College, Cambridge, in 1867 to read for the Mathematical Tripos. An appointment in 1872 with the lighthouse department of the Chance Optical Works in Birmingham directed his attention to electrical engineering. His most noteworthy contribution to lighthouse engineering was an optical system to produce flashing lights that distinguished between individual beacons. His extensive researches on the dielectric properties of glass were recognized when he was elected to a Fellowship of the Royal Society at the age of 29. Moving to London in 1877 he became established as a consulting engineer at a time when electricity supply was about to begin on a commercial scale. During the remainder of his life, Hopkinson's researches resulted in fundamental contributions to electrical engineering practice, dynamo design and alternating current machine theory. In making a critical study of the Edison dynamo he developed the principle of the magnetic circuit, a concept also arrived at by Gisbert Kapp around the same time. Hopkinson's improvement of the Edison dynamo by reducing the length of the field magnets almost doubled its output. In 1890, in addition to-his consulting practice, Hopkinson accepted a post as the first Professor of Electrical Engineering and Head of the Siemens laboratory recently established at King's College, London. Although he was not involved in lecturing, the position gave him the necessary facilities and staff and student assistance to continue his researches. Hopkinson was consulted on many proposals for electric traction and electricity supply, including schemes in London, Manchester, Liverpool and Leeds. He also advised Mather and Platt when they were acting as contractors for the locomotives and generating plant for the City and South London tube railway. As early as 1882 he considered that an ideal method of charging for the supply of electricity should be based on a two-part tariff, with a charge related to maximum demand together with a charge for energy supplied. Hopkinson was one the foremost expert witnesses of his day in patent actions and was himself the patentee of over forty inventions, of which the three-wire system of distribution and the series-parallel connection of traction motors were his most successful. Jointly with his brother Edward, John Hopkinson communicated the outcome of his investigations to the Royal Society in a paper entitled "Dynamo Electric Machinery" in 1886. In this he also described the later widely used "back to back" test for determining the characteristics of two identical machines. His interest in electrical machines led him to more fundamental research on magnetic materials, including the phenomenon of recalescence and the disappearance of magnetism at a well-defined temperature. For his work on the magnetic properties of iron, in 1890 he was awarded the Royal Society Royal Medal. He was a member of the Alpine Club and a pioneer of rock climbing in Britain; he died, together with three of his children, in a climbing accident.

[br]

Principal Honours and Distinctions

FRS 1878. Royal Society Royal Medal 1890. President, Institution of Electrical Engineers 1890 and 1896.

Bibliography

7 July 1881, British patent no. 2,989 (series-parallel control of traction motors). 27 July 1882, British patent no. 3,576 (three-wire distribution).

1901, Original Papers by the Late J.Hopkinson, with a Memoir, ed. B.Hopkinson, 2 vols, Cambridge.

Further Reading

J.Greig, 1970, John Hopkinson Electrical Engineer, London: Science Museum and HMSO (an authoritative account).

—1950, "John Hopkinson 1849–1898", Engineering 169:34–7, 62–4.

GW