WATER
JET CUTTING
INTRODUCTIONDoff In
the battle to reduce costs, engineering and manufacturing departments are constantly on the lookout for an edge. The
water jet process provides many unique capabilities and advantages that can
prove very effective in the cost battle. Learning more about the water jet
technology will give us an opportunity to put these cost-cutting capabilities
to work. Beyond cost cutting, the water jet process is recognized as the most
versatile and fastest growing process in the world. Water jets are used in high
production applications across the globe. They compliment other technologies
such as milling, laser, EDM, plasma and routers. No poisonous gases or liquids
are used in water jet cutting, and water jets do not create hazardous materials
or vapors. No heat effected zones or mechanical stresses are left on a water
jet cut surface. It is truly a versatile, productive, cold cutting process. The
water jet has shown that it can do things that other technologies simply
cannot. From cutting whisper, thin details in stone, glass and metals; to rapid
whole drilling of titanium; for cutting of food, to the killing of pathogens in
beverages and dips, the water jet has proven itself unique.
Most water jet cutting theories explain water jet
cutting as a form of micro erosion as described here .Water jet cutting works
by forcing a large volume of water through a small orifice in the nozzle. The
constant volume of water traveling through a reduced cross sectional area
causes the particles to rapidly accelerate. This accelerated stream leaving the
nozzle impacts the material to be cut. The extreme pressure of the accelerated
water particles contacts a small area of the work piece. In this small area thework
piece develops small cracks due to stream impact. The water jet washes away the
material that "erodes" from the surface of the work piece. The crack
caused by the water jet impact is now exposed to the water jet. The extreme
pressure and impact of particles in the following stream cause the small crack
to propagate until the material is cut through.
WORKING PRINCIPLE
For cutting thicker materials some abrasives like garnet is added to
pure water jet. This is called abrasive water jet and cutting using abrasive
jet is called abrasive jet cutting. The high-pressure abrasive jet cuts thicker
and harder materials. Abrasive jet cutting is advancement in the field of water
jet cutting
WATERJET CUTTING PROCESS
Pure water jet is the original water cutting method. Water jet cutting uses only a pressurized stream of water to
cut through material. This type of cutting is limited to material with
naturally occurring small cracks or softer materials like disposable
diapers, tissue paper, and automotive interiors. In the cases of tissue paper
and disposable diapers the water jet process creates less moisture on the
material than touching or breathing on it. The figure shows the water jet
cutting process.
In this process water is
increased in pressure by high-pressure pump to about 40000-60000 PSI and is
forced through the orifice on to the target material. This
high-pressure water on striking the surface performs the machining operation.
The potential energy contained in the water is converted in the process to
kinetic energy, i.e., into jet velocity, thus achieving its "cutting"
effect.
PURE WATERJET
utting head.
In water jet
cutting, the material removal process can be described as a supersonic erosion
process. It is not pressure, but stream velocity that tears away microscopic
pieces or grains of material. Pressure and velocity are two distinct forms of
energy. The pump’s water pressure is converted to the other form of energy,
water velocity by a tiny jewel. A jewel is affixed to the end of the plumbing
tubing. The jewel has a tiny hole in it. The pressurized water passes through
this tiny opening changing the pressure to velocity. At approximately 40,000
psi the resulting stream that passes out of the orifice is traveling at Mach 2.
And at 60,000 psi the speed is over Mach 3.
ABRASIVE WATER JET CUTTING
The cutting ability of
water jet machining can be improved drastically by adding hard and sharp
abrasive particles into the water jet. Thus, WJM is typically used to cut so
called “softer” and “easy-to-machine” materials like thin sheets and foils,
non-ferrous metallic alloys, wood, textiles, honeycomb, polymers, frozen meat,
leather etc, but the domain of “harder and “difficult-to-machine” materials
like thick plates of steels, aluminum and other commercial materials, metal
matrix and ceramic matrix composites, reinforced plastics, layered composites
etc are reserved for AWJM.
Other than cutting
(machining) high pressure water jet also finds application in paint removal,
cleaning, surgery, peening to remove residual stress etc. AWJM can as well be
used besides cutting for pocket milling, turning ,drilling etc .One of the
strategic areas where robotic AWJM is finding critical application is dismantling
of nuclear plants.
MACHINE
Any
standard abrasive water jet machining (AWJM) system using entrained AWJM
methodology consists of following modules.
• LP booster pump
•
Hydraulic unit
•
Additive Mixer
•
Intensifier
•
Accumulator
•
Flexible high
pressure transmission line
•
On-off valve
•
Orifice
•
Mixing Chamber
•
Focussing tube
or inserts
•
Catcher
•
CNC table
•
Abrasive
metering device
•Catcher
MIXING
Schematic
view of mixing process
Mixing means gradual
entrainment of abrasive particles within the water jet and finally the abrasive
water jet comes out of the focusing tube or the nozzle.
During mixing process,
the abrasive particles are gradually accelerated due to transfer of momentum
from the water phase to abrasive phase and when the jet finally leaves the
focusing tube, both phases, water and abrasive, are assumed to be at same
velocity.
APPLICATIONS OF WATERJET CUTTING
APPLICATIONS OF WATERJET CUTTING
Flexible water jet cutting technology is used
in practically all sectors of industry: Aerospace, residential and industrial
construction, mechanical engineering, the glass industry, the wood, textiles
and paper industries, the automotive and its supplier industries, and the
electrical, electronic and foodstuffs industries. Unlike traditional thermal
cutting methods, water jet cutting technology wins friends with its high level
of cost-effectiveness and flexibility. The most diverse materials, from metal
via plastics up to and including granite, can be quickly and precisely worked
using a high-pressure jet of water. Material thickness of 150 mm or more
present no difficulties to our cutting processes. The water jet achieves
optimum cut-edge qualities on both simple and extremely complex contours.
General 2D applications
•
Sheet metal: Stainless steel, carbon steel, high-alloy nickel steels, aluminum,
titanium, copper
• Building: Decorative stone, marble, granite, tiles, plasterboard, glass and mineral wool
• Glass: Laminated glass, safety glass, and bulletproof glass
• Foodstuffs: Baked goods, deep-frozen products and fish
• Paper: Cardboard, corrugated cardboard, printing papers
• Miscellaneous: Plywood, leather, textiles, composites, rubber, plastics, sealing materials and foams .
• Building: Decorative stone, marble, granite, tiles, plasterboard, glass and mineral wool
• Glass: Laminated glass, safety glass, and bulletproof glass
• Foodstuffs: Baked goods, deep-frozen products and fish
• Paper: Cardboard, corrugated cardboard, printing papers
• Miscellaneous: Plywood, leather, textiles, composites, rubber, plastics, sealing materials and foams .
3D and robot applications:
• Abrasive: Titanium, aluminum and stainless steel motor-vehicle
components, turbine blades, decorative stone or marble.
• Pure water: Motor-vehicle elements such as carpets, door-trims, fenders,
dashboards, instrument panels, rear shelves.
Application
The applications and materials,
which are generally machined using WJ and AWJ, are given below:
1.
Paint removal
2.
Cleaning
3.
Cutting soft materials
4.
Cutting frozen meat
5.
Textile, Leather
industry
6.
Mass Immunization
7.
Surgery
8.
Preening
9.
Cutting
10. Pocket Milling
11. Drilling
12. Turning
13. Nuclear Plant Dismantling
Materials
•
Steels
•
Non-ferrous alloys
•
Ti alloys, Ni- alloys
•
Polymers
•
Honeycombs
•
Metal Matrix Composite
•
Ceramic Matrix Composite
•
Concrete
•
Stone – Granite
•
Wood
•
Reinforced plastics
•
Metal Polymer Laminates
•
Glass Fiber Metal Laminates
• The AWJ easily machines
titanium, nickel alloys and very hard brittle materials
• It is a cold cutting
process, machining without creating thermal distortions or thermally driven
changes to the metallurgical and crystal structure (no brittle recast or
micro-cracks as left by laser and EDM)
• The work piece sees very
low tool loads with the abrasive-water jet and machining delicate part features
is an option
• Glass and ceramic
materials can be machined to complex shapes without the sub-surface flaws
created during grinding
• Drilling small, deep
holes is easily performed with the AWJ
• AWJ cuts more materials
and is faster than EDM
• AWJ cuts more materials and is
faster than laser with thick materials
The AWJ has
many advantages over other machining technologies, but has remained a niche
market in part because of limitations involved in machining to close
tolerances. The capabilities at Ormond make it feasible to address closer
tolerance work and take advantage of AWJ benefits over a broader range of
applications.
•
One of the main
disadvantages of water jet cutting is that a limited number of materials can be
cut economically. While it is possible to cut tool steels, and other hard
materials, the cutting rate has to be greatly reduced, and the time to cut a
part can be very long. Because of this, water jet cutting can be very costly
and outweigh the advantages.
•
Another disadvantage is that very thick parts
can not be cut with water jet cutting and still hold dimensional accuracy. If
the part is too thick, the jet may dissipate some, and cause it to cut on a diagonal,
or to have a wider cut at the bottom of the part than the top. It can also
cause a rough wave pattern on the cut surface.
•
Taper is also a
problem with water jet cutting in very thick materials. Taper is when the jet
exits the part at a different angle than it enters the part, and can cause
dimensional inaccuracy. Decreasing the speed of the head may reduce this,
although it can still be a problem.
WATER JETS VS. OTHER MACHINING PROCESSES
WATER JETS VS. OTHER MACHINING PROCESSES
Flame
Cutting:
Water jets would make a
great compliment to a flame cutting where more precision or higher quality is
required, or for parts where heating is not good, or where there is a need to
cut a wider range of materials.
Milling:
Water jets are used a
lot for complimenting or replacing milling operations. They are used for
roughing out parts prior to milling, for replacing milling entirely, or for
providing secondary machining on parts that just came off the mill. For
this reason, many traditional machine shops are adding water jet capability to
provide a competitive edge.
Punch
Press:
Some stamping houses
are using water jets for fast turn-around, or for low quantity or prototyping
work. Water jets make a great complimentary tool for punch presses and
the like because they offer a wider range of capability for similar parts.
Environmental issues
Nowadays, every manufacturing process is being re-evaluated
in terms of its impact on the environment. For example, use of conventional
coolants in machining and grinding is being looked upon critically from the
point of view of its impact on environment. The environmental issues relevant
to AWJM are :-
• Water recycling
• spent water disposal
• Chip recovery
• Abrasive
recovery and reuse
Environmental
issues and concerns have lead the researchers to use such mediums and abrasives
that do not require disposal, recycling or lead to pollution. Work is going on
in the area of high-pressure cryogenic jet machining (Fig. 16) where liquid
nitrogen replaces the water phase and dry ice crystals (solid CO2 crystals)
replace the abrasive phase
leading to no need of disposal or waste generation. The removed work
material in the form of microchips can be collected much easily reducing the
chances of environmental degradation.
FUTURE
SCOPE
Since its development, water jet machining has seen
many improvements in its design. Water jet cutting
technology is one of the fastest growing major machine tool processes in the
world due to its versatility and ease of operation. Manufacturers are realizing
that there are virtually no limits to what water jets are capable of cutting
and machining. Machine shops of all sizes are realizing greater efficiency and
productivity by implementing UHP water jets in their operations. Water jets are
becoming the machine tool of choice for many shops. Since abrasive water jet
(AWJ) technology was first invented by Flow in the early 1980s, the technology
has rapidly evolved with continuous research and development.
What
makes water jets so popular? Water jets require few
secondary operations, produce net-shaped parts with no heat-affected zone, heat
distortion, or mechanical stresses caused by other cutting methods, can cut with
narrow kerfs, and can provide better usage of raw material since parts can be
tightly nested. As a result of the Flow Master PC control system and intuitive
operation, water jets are extremely easy to use. Typically, operators can be
trained in hours and are producing high quality parts in hours. Additionally, water
jets can cut virtually any material, leaving a satin-smooth edge. These
benefits add up to significant cost savings per part in industries that have
traditionally defined productivity by cost per hour.
The
latest development in the field of water jet cutting is the use of super water
for cutting, which enhances both abrasive and non-abrasive water jet cutting.
CONCLUSION
—
Relatively new
technology has caught on quickly and is replacing century-old methods for
manufacturing.
—
Water Jet Cutting is
not only used in typical machining applications, but also in food and
soft-goods industries.
—
As material and pump technology
advances faster cutting rates, longer component life and tighter tolerances
will be achievable.
—
Water Jet Machining paves
the way for new machining processes that embrace simplicity and have a small
environmental impact.
REFERENCE
en.wikipedia.org
www.o-keating.com
