Thursday, 30 May 2013

High Velocity Hydroforming (HVH)




Analogous to conventional hydroforming, in high rate hydroforming the force is applied via a solid, fluid or gaseous working medium and thus, only one die is required, but in contrast to the quasistatic case, Pascal�s principle is no longer valid here. Instead of a homogeneous pressure distribution in the fluid, here a pressure impulse propagates through the fluid as a pressure wave or a shockwave (e.g. [Lan93]). This pressure wave accelerates the workpiece in its propagation direction. According to the initiation mechanisms of the shockwave
  • electrohydraulic forming,
  • explosive forming and propellant forming, and
  • the hydropunch process
can be distinguished.

Characteristics of a shockwave

A shockwave is characterized by
  • an expansion velocity that is (slightly) higher than the specific sonic speed of the working medium,
  • an extremely fast pressure rise in the range of a few nanoseconds in low energy applications (e.g. in an lithotripter) up to the range of a few microseconds in higher energy applications (i.e. industrial applications as forming or destroying ceramic cores inside castings), and
  • a spatial form and expansion that depends on and can be influenced via the setup. Reflectors can be used for directing or focusing the shockwave.
However, in an industrial application the forming process is the result of a pressure wave but not of the shockwave. The expansion velocity of the shockwave is typically slightly higher than the specific sonic speed of the working medium but the measured forming velocity is much lower. For example, electrohydraulic forming tests with shockwave generation inside water result in an average forming velocity of 67 m/s. The velocity maximum at the end of the forming process is between 250 and 300 m/s. For comparison, the sonic speed in water is 1,450 m/s. On the other hand, it is possible to form metal plates which are not in contact with the water surface, depending on the used pulse energy and the electrode distance from the water surface. These perceptions explain that the electrohydraulic forming process is a result firstly of the accelerated water in consequence of a water steam bubble generated by the plasma channel and secondly of the inertia of masses of the workpiece.

Explosive forming

The earliest known publication about impulse forming, an English patent, is related to tube joining and tube expansion, respectively, by means of an explosive charge [GB 21840]. The first patent dealing with the explosive forming of sheet metal is [US 939702].

Process principle and variants

During explosive forming the shockwave is initiated by a detonating high explosive. Here, one can differentiate between the contact operation and the standoff operation. In the contact operation, the surface of the workpiece is covered with the explosive and the detonation wave accelerates the workpiece directly. By contrast, in the standoff operation, workpiece and die are positioned in a working medium and the explosive is ignited in some distance to the workpiece initiating a shockwave that travels through the working medium before accelerating the workpiece (e.g. [Neu88]). principles
In the standoff operation, the peak pressures are typically lower than in case of the contact operation [Bru68]. The reason is that friction, heat conduction and expansion result in fractional dissipation of the detonation energy.

Selected process parameters

According to [Neu88], important parameters for the process design are
  • the distance between the mass and the explosive
  • the brisance of the explosive, and
  • the state of the working medium (gaseous, fluid or granular).
    In case of granular working media as e.g. sand and metal or wooden chips, also
  • the density of the working medium, and
  • the humidity of the working medium are decisive with regard to the efficiency of the energy transfer and, consequently, considering the pressure applied to the workpiece.
Furthermore, the explosive is formed to different shapes according to the application. In the standoff operation for drawing of sheets, spherical shapes are used, while tube bulging is done using twines. Cutting, embossing, and cladding of sheets are usually done in a contact operation using foils or powder. [Lan93].


Propellant forming

Process principle

As in explosive forming, in propellant forming, the energy is provided by a detonation but in contrast to the previously described processes, here, a detonating gas mixture is actuator of the process as well as working medium [Web06]. After the ignition, the detonation zone propagates through the detonation tube and the forming process begins when the detonation reaches the workpiece. In comparison to forming with high explosives, the strain rates in propellant forming are significantly lower and the duration of the detonation can take up to some tenths of a second and, thus, is much longer than in case of high explosives [Bru68]. For a reliable process, the concentration and the mixing of the explosive gases as e.g. hydrogen (H2), methane (CH4), propane (C3H8), butane (C4H10) or other hydrocarbons (CnHm) and an oxidant as oxygen (O2) or air as well as the ignition system are decisive [Bru68, Neu90, Vov99].

propellant_forming


Electrohydraulic forming

Process principle

During electrohydraulic forming stored electric energy is suddenly discharged through a spark gap so that the surrounding working medium (e.g. water) is ionized and vaporizes, initiating a shockwave.

Process variants

According to the type of spark gap
  • electrohydraulic forming with discharge through a wire (i.e. the electrodes are connected to each other by a wire bridge) and
  • electrohydraulic forming with discharge through a gap (i.e. there is no connection between the electrodes) can be differentiated.
According to [Wil64], the setup with a wire bridge is more efficient and can be operated at lower voltages and longer distances between the electrodes, while in case of the setup with discharge through a gap, the process preparation is easier and faster. electrohydraulic_forming
The efficiency of an electrohydraulic process can be increased by using a suitable reflector. The reflector design needs to be done taking into account the specific forming task and considering that every redirection of the pressure war is related to energy losses. As shown in [Kle01], the shockwave can be focused by using an elliptic reflector geometry. Spherically spreading from the spark gap, which is positioned in the first focal point of the ellipse, the shockwave is reflected and converges in the second focal point. Other reflector geometries can be used for bulging tubes of different dimensions. 1_1_electrohydraulic_forming2.jpg


Hydropunch process

The most important high rate mechanical forming operation is the hydropunch process [Rat71, Tom69]. As shown in Figure 2, the principle setup of this technology consists of a compressed air system, accelerating a plunger up to velocities in the range of 30m/s before it dips into the working medium. As aresult of the impact, the fluid is compressed and pressed into the tool unit. The resulting pressure forms the workpiece into the die cavity. Hydropunch process

Electro Hydraulic Forming Process

 

 

 

Process principle

During electrohydraulic forming stored electric energy is suddenly discharged through a spark gap so that the surrounding working medium (e.g. water) is ionized and vaporizes, initiating a shockwave.

Process variants

According to the type of spark gap
  • electrohydraulic forming with discharge through a wire (i.e. the electrodes are connected to each other by a wire bridge) and
  • electrohydraulic forming with discharge through a gap (i.e. there is no connection between the electrodes) can be differentiated.
According to [Wil64], the setup with a wire bridge is more efficient and can be operated at lower voltages and longer distances between the electrodes, while in case of the setup with discharge through a gap, the process preparation is easier and faster. electrohydraulic_forming
The efficiency of an electrohydraulic process can be increased by using a suitable reflector. The reflector design needs to be done taking into account the specific forming task and considering that every redirection of the pressure war is related to energy losses. As shown in [Kle01], the shockwave can be focused by using an elliptic reflector geometry. Spherically spreading from the spark gap, which is positioned in the first focal point of the ellipse, the shockwave is reflected and converges in the second focal point. Other reflector geometries can be used for bulging tubes of different dimensions. 1_1_electrohydraulic_forming2.jpg

Wednesday, 29 May 2013

Difference Between jig and fixture




 INTRODUCTION
The jigs and fixtures are the economical ways to produce a component in mass. So jigs
and fixtures are used and serve as one of the most important facility of mass production
system. These are special work holding and tool guiding device. Quality of the
performance of a process largely influenced by the quality of jigs and fixtures used for
this purpose. What makes a fixture unique is that each one is built to fit a particular part
or shape. The main purpose of a fixture is to locate and in the cases hold a workpiece
during an operation. A jig differs from a fixture in the sense that it guides the tool to its
correct position or towards its correct movement during an operation in addition to
locating and supporting the workpiece.
An example of jig is when a key is duplicated, the original key is used as base for the
path reader which guides the movement of tool to make its duplicate key. The path
reader of a CWC machine here works as a jig and the original is called template.
Sometimes the template and jig both are the name of same part of a manufacturing
system.





Structure
1 Introduction
Objectives
2 Purpose and Advantages of Jigs and Fixtures
3 Important Considerations while Designing Jigs and Fixtures
4 Meaning of Location
5 Principles of Locations
6 Different Methods Used for Locations
7 Clamping
8 Different Types of Clamps
9 Jigs
10 Different Types of Jigs
11 Fixtures
12 Summary
Downlod pdf on  jig and fixture
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Data Structures Through C - Yashavant Kanetkar


                                               books on data structure.
Data Structures Through C (With CD-ROM), written by Yashavant Kanetkar, is a guidebook that seeks to explain the fundamentals of data structures, a concept related to computer programming. It takes an innovative approach to the subject by using a concrete language like C to explain concepts, instead of merely relying on algorithms as many other books on the subject often do.

The book explores concepts like algorithm analysis, arrays, strings, linked lists, queues, stacks, sparse matrices, searching and sorting, graphs, and trees. In fact, readers can actually experience procedures like the construction of a binary tree, traversing of a doubly linked list, and sorting of an array through the carefully designed animations presented on the CD-ROM accompanying the book.

The concepts are presented in a lucid manner. Numerous examples and programs are also included to help readers get a better understanding of the complex operations performed on data structures.

Download Free pdf Data Structures Through C - Yashavant Kanetkar

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High Power Stirling Engine

       



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Flame Gulping Engine

       



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tiniest engine

       



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Monday, 27 May 2013

How Cube Gear works?

       



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These Gears Really Work?

       



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Mechanical Principles (1930) by Ralph Steiner

       



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Column Gear

       



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Brain gear machine

       



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How does gear system change speed ?

       



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Gears Manufacturing Methods

       



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How a Differential Works and Types of Differentials

       



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Gear Design | Spur Gears

       



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Gears and Gear Cutting and Manufacturing

       



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Rinspeed's first underwater Car

       



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Ferrari V12 HY-KERS Technology

       



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Ferrari V12 Engine

       



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BMW - Production Engine M Cars V8

       



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Audi TDI - How it's made

       



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BMW 3 Series BMW Munich Plant Production

       



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Mercedes-Benz E-Class Production

       



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Mercedes-Benz SLR McLaren Production

       



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Mercedes-Benz plant production of cars part 2 (2/3)

       



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Mercedes-Benz plant production of cars part 3 (3/3)

       



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Mercedes-Benz plant production of cars part 1 (1/3)

       



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Tuesday, 21 May 2013

Fox and McDonald's Introduction to Fluid Mechanics, 8th Edition

                                 

One of the bestselling books in the field, Introduction to Fluid Mechanics continues to provide readers with a balanced and comprehensive approach to mastering critical concepts. The new seventh edition once again incorporates a proven problem-solving methodology that will help them develop an orderly plan to finding the right solution. It starts with basic equations, then clearly states assumptions, and finally, relates results to expected physical behavior. Many of the steps involved in analysis are simplified by using Excel.

Download Free pdf Fox and McDonald's Introduction to Fluid Mechanics, 8th Edition

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Wednesday, 15 May 2013

Electrical Engineering and Computer Science

       



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Electronics & Computer Engineering Technology with Jorgette

       



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Computer Engineering

       



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How to Get into MIT ?

       



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How to succeed in engineering

       



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PC vs Mac Vs Linux

       



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Mac vs PC vs Linux

       



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Windows vs Mac vs Linux

       



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C++ Programmer

       



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PHP vs. Python vs. Ruby vs. Java vs. .NET

       



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A day in the life of a Computer Science student

       



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Is Computer Science only for geeks?

       



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Is Computer Science only about programming?

       



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