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Chapter 1
1.1Introduction:-
A water jet cutter, also known as a water jet or water jet, is an industrial tool capable
of cutting a wide variety of materials using a very high-pressure jet of water, or a
mixture of water and an abrasive substance. The term abrasive jet refers specifically
to the use of a mixture of water and abrasive to cut hard materials such as metal
or granite, while the terms pure water jet and water-only cutting refer to water jet
cutting without the use of added abrasives, often used for softer materials such as
wood or rubber.
Water jet cutting is often used during fabrication of machine parts. It is the preferred
method when the materials being cut are sensitive to the high temperatures generated
by other methods. Water jet cutting is used in various industries,
including mining and aerospace, for cutting, shaping, and reaming.
Fig1.1:- Water jet cutter
1
Cutting steel, concrete, glass and marble with water - sounds a bit far-fetched doesn’t
it? Way back in the 1950s, a forestry engineer by the name of Norman Franz started
fiddling around with a high-pressure water stream to cut lumber. His aim was to
streamline the process and reduce the strain on traditional cutting equipment such as
saw blades, which easily became blunt and needed replacing. From these humble
beginnings an idea was born, and over the next couple of decades, water cutting
became an unparalleled method for cutting materials of all types, shapes and sizes.
FIG1.2:- nozzle
The end product? A water jet cutter – a machine capable of slicing metal and other
materials such as granite and marble with unbelievable accuracy. It does this by using
a jet of water at high velocity and pressure, sometimes mixed with an abrasive
substance, depending on the material that is being cut. Water jet cutters are usually
used to cut materials such as rubber, foam, plastics, leather, composites, stone, tiles,
2
metals, food and paper. However, they can’t cut tempered glass, diamonds and certain
ceramics
Fig1.3:- water jet cutter operation.
3
CHAPTER 2
2.2 HISTORY:-
While using high-pressure water for erosion dates back as far as the mid-
1800s with hydraulic mining, it was not until the 1930s that narrow jets of water
started to appear as an industrial cutting device. In 1933, the Paper Patents Company
in Wisconsin developed a paper metering, cutting, and reeling machine that used a
diagonally moving water jet nozzle to cut a horizontally moving sheet of continuous
paper.[2] These early applications were at a low pressure and restricted to soft
materials like paper.
Water jet technology evolved in the post-war era as researchers around the world
searched for new methods of efficient cutting systems. In 1956, Carl Johnson of
Durox International in Luxembourg developed a method for cutting plastic shapes
using a thin stream high-pressure water jet, but those materials, like paper, were soft
materials.[3] In 1958, Billie Schwacha of North American Aviation developed a
system using ultra-high-pressure liquid to cut hard materials.[4] This system used a
100,000 psi (690 MPa) pump to deliver a hypersonic liquid jet that could cut high
strength alloys such as PH15-7-MO stainless steel. Used as a honeycomb laminate on
the Mach 3 North American XB-70 Valkyrie, this cutting method resulted in
delaminating at high speed, requiring changes to the manufacturing process.[5]
While not effective for the XB-70 project, the concept was valid and further research
continued to evolve water jet cutting. In 1962, Philip Rice of Union Carbide explored
using a pulsing water jet at up to 50,000 psi (345 MPa) to cut metals, stone, and other
materials.[6] Research by S.J. Leach and G.L. Walker in the mid-1960s expanded on
traditional coal water jet cutting to determine ideal nozzle shape for high-pressure
water jet cutting of stone,[7] and Norman Franz in the late 1960s focused on water jet
cutting of soft materials by dissolving long chain polymers in the water to improve the
cohesiveness of the jet stream.[8]
4
In the early 1970s, the desire to improve the durability of the water jet nozzle led Ray
Chadwick, Michael Kurko, and Joseph Corriveau of the Bendix Corporation to come
up with the idea of using corundum crystal to form a water jet orifice,[9] while Norman
Franz expanded on this and created a water jet nozzle with an orifice as small as
0.002 inches (0.05 mm) that operated at pressures up to 70,000 psi (483 MPa).[10] John
Olsen, along with George Hurlburt and Louis Kapcsandy at Flow Research (later
Flow Industries), further improved the commercial potential of the water jet by
showing that treating the water beforehand could increase the operational life of the
nozzle.[11]
Fig 2.1 old model of water jet system
2.2.1 1800:-
Hydraulic mining had its precursor in the practice of ground sluicing, a
development of which is also known as "hushing", in which surface streams of water
were diverted so as to erode gold-bearing gravels. This was originally used in the
Roman empire in the first centuries AD and BC, and expanded throughout the empire
wherever alluvial deposits occurred[2] The Romans used ground sluicing to remove
overburden and the gold-bearing debris in Las Medullas of Spain,
5
and Dolaucothi in Britain. The method was also used in Elizabethan
England & Wales (or rarel for developing lead, tin and copper mines.1
Water was used on a large scale by Roman engineers in the first centuries BC and AD
when the Roman empire was expanding rapidly in Europe. Using a process later
known as hushing, the Romans stored a large volume of water in a reservoir
immediately above the area to be mined; the water was then quickly released. The
resulting wave of water removed overburden and exposed bedrock. Gold veins in the
bedrock were then worked using a number of techniques, and water power was used
again to remove debris. The remains at Las Medullas and in surrounding areas
show badland scenery on a gigantic scale owing to hydraulic king of the rich alluvial
gold deposits. Las Medullas is now a UNESCO World Heritage site. The site shows
the remains of at least seven large aqueducts of up to 30 miles in length feeding large
supplies of water into the site. The gold-mining operations were described in vivid
terms by Pliny the Elder in his Naturalist Historia published in the first century AD.
Pliny was a procurator in Hispania Terraconensis in the 70's and must have witnessed
for himself the operations. The use of hushing has been confirmed by field survey
and archaeology at Dolaucothi in South Wales, the only known Roman gold mine
in Britain.
The modern form of hydraulic mining, using jets of water directed under very high
pressure through hoses and nozzles at gold-bearing upland paleo gravels, was first
used by Edward Matteson near Nevada City, California in 1853 during the California
Gold Rush.[3] Matteson used canvas hose which was later replaced with crinoline hose
by the 1860s.[4] In California, hydraulic mining often brought water from higher
locations for long distances to holding ponds several hundred feet above the area to be
mined. California hydraulic mining exploited gravel deposits, making it a form
of placer mining.
Early placer miners in California discovered that the more gravel they could process,
the more gold they were likely to find. Instead of working with pans, sluice boxes,
long toms, and rockers, miners collaborated to find ways to process larger quantities
of gravel more rapidly. Hydraulic mining became the largest-scale, and most
devastating, form of placer mining. Water was redirected into an ever-narrowing
channel, through a large canvas hose, and out through a giant iron nozzle, called a
6
"monitor." The extremely high pressure stream was used to wash entire hillsides
through enormous sluices.
By the early 1860s, while hydraulic mining was at its height, small-scale placer
mining had largely exhausted the rich surface placers, and the mining industry turned
to hard rock (called quartz mining in California) or hydraulic mining, which required
larger organizations and much more capital. By the mid-1880s, it is estimated that 11
million ounces of gold (worth approximately US$7.5 billion at mid-2006 prices) had
been recovered by hydraulic mining in the California Gold Rush.
2.2.2 1850:-
High-pressure vessels and pumps became affordable and reliable with the advent of
steam power. By the mid-1850s, steam locomotives were common and the first
efficient steam-driven fire engine was operational.[12] By the turn of the century, high-
pressure reliability improved, with locomotive research leading to a six fold increase
in boiler pressure, some reaching 1600 psi (11 MPa). Most high-pressure pumps at
this time, though, operated around 500–800 psi (3–6 MPa).
7
High-pressure systems were further shaped by the aviation, automotive, and oil
industries. Aircraft manufacturers such as Boeing developed seals for hydraulically
boosted control systems in the 1940s,[13] while automotive designers followed similar
research for hydraulic suspension systems.[14] Higher pressures in hydraulic systems in
the oil industry also led to the development of advanced seals and packing to prevent
leaks.[15]
These advances in seal technology, plus the rise of plastics in the post-war years, led
to the development of the first reliable high-pressure pump. The invention
of Marlex by Robert Banks and John Paul Hogan of the Phillips Petroleum company
required a catalyst to be injected into the polyethylene.[16] McCartney Manufacturing
Company in Baxter Springs, Kansas, began manufacturing these high-pressure pumps
in 1960 for the polyethylene industry.[17] Flow Industries in Kent, Washington set the
groundwork for commercial viability of water jets with John Olsen’s development of
the high-pressure fluid intensifier in 1973,[18] a design that was further refined in 1976.[19] Flow Industries then combined the high-pressure pump research with their water
jet nozzle research and brought water jet cutting into the manufacturing world.
8
2.2.3 1935:-
While cutting with water is possible for soft materials, the addition of an abrasive
turned the water jet into a modern machining tool for all materials. This began in 1935
when the idea of adding an abrasive to the water stream was developed by Elmo
Smith for the liquid abrasive blasting.[20] Smith’s design was further refined by Leslie
Terrell of the Hydro blast Corporation in 1937, resulting in a nozzle design that
created a mix of high-pressure water and abrasive for the purpose of wet blasting.[21] Producing a commercially viable abrasive water jet nozzle for precision cutting
came next by Dr. Mohamed Hashish who invented and led an engineering research
team at Flow Industries to develop the modern abrasive water jet cutting technology.[22] Dr. Hashish, who also coined the new term "Abrasive Water jet" AWJ, and his
team continued to develop and improve the AWJ technology and its hardware for
many applications which is now in over 50 industries worldwide. A most critical
development was creating a durable mixing tube that could withstand the power of the
high-pressure AWJ, and it was Boride Products (now Kennametal) development of
their ROCTEC line of ceramic tungsten carbide composite tubes that significantly
increased the operational life of the AWJ nozzle.[23] Current work on AWJ nozzles is
on micro abrasive water jet so cutting with jets smaller than 0.015 inch in diameter
can be commercialized
9
2.2.4 1990:-
As water jet cutting moved into traditional manufacturing shops, controlling the cutter
reliably and accurately was essential. Early water jet cutting systems adapted
traditional systems such as mechanical pantographs and CNC systems based on John
Parsons’ 1952 NC milling machine and running G-code.[24] Challenges inherent to
water jet technology revealed the inadequacies of traditional G-Code, as accuracy
depends on varying the speed of the nozzle as it approaches corners and details.[25] Creating motion control systems to incorporate those variables became a major
innovation for leading water jet manufacturers in the early 1990s, with Dr John Olsen
of OMAX Corporation developing systems to precisely position the water jet
nozzle[26] while accurately specifying the speed at every point along the path,[27] and
also utilizing common PCs as a controller. The largest water jet manufacturer, Flow
International (a spinoff of Flow Industries), recognized the benefits of that system and
licensed the OMAX software, with the result that the vast majority of water jet cutting
machines worldwide are simple to use, fast, and accurate.[28]
10
CHAPTER 3
3.1 Working:-
At its most basic, water flows from a pump, through plumbing and out a cutting head.
It is simple to explain, operate and maintain. The process, however, incorporates
extremely complex materials technology and design.
To generate and control water at pressures of 87,000 psi requires science and
technology not taught in universities. At these pressures a slight leak can cause
permanent erosion damage to components if not properly designed.
Thankfully, the water jet manufacturers take care of the complex materials technology
and cutting-edge engineering. The user need only be knowledgeable in the basic water
jet operation.
Flow machines are designed to operate as both pure and abrasive water jets. A pure
water jet is used to cut soft materials, and within just 2 minutes the very same water
jet can be transformed into an abrasive water jet to cut hard materials. With any type,
the water must first be pressurized.
Fig 3.1 horizontal water jet cutter
11
3.1.1 High pressure water jet cutting:-
Water is pressurized to very high pressures, in excess of 50,000 psi. This
pressurization is accomplished with the use of pumps of various designs, discussed
next in this chapter.
The high pressure water is transported through a series of stainless steel tubes to a
cutting head. Depending upon the material being cut, the cutting head can be either a
"pure water cutting head" or an "abrasive cutting head."
In the cutting head, the high pressure water is forced through a small diameter orifice.
The diameter of this orifice is anywhere from 0.004" to 0.020". This step converts the
pressure of the water jet stream into speed. We go from potential energy to kinetic
energy. Coming out of the orifice, the water jet stream is moving at 2200 mph or
faster. Higher pressure results in higher speed. Smaller diameter orifices yield a faster
water jet stream, but also a stream with less kinetic energy since there is not as much
water available to accelerate abrasive grains to full speed.
In a pure water cutting head, the water immediately exits the cutting head after
passing through the orifice. The speed and power of the water jet stream is enough to
cut soft or thin materials like foam, rubber, soft wood, plastics, carpet, food, car
headliners, circuit boards and more.
In an abrasive cutting head, a very hard abrasive, typically garnet, is fed into the water
jet stream. The abrasive particles are accelerated to near the speed of the water jet
stream. This gives the abrasive particles much power. The abrasive water jet stream
now travels down through an abrasive nozzle, or mixing tube, approximately 3 inches
long with an inner diameter of between .030" and 0.050". The mixture of water and
abrasive exits the abrasive nozzle and will cut hard materials like metals, stone,
acrylic, ceramic, composites, phenolic and porcelain.
A CNC control will move the cutting head in up to 6 axes of motion to cut the
targeted work piece.
12
3.2 Types of pumps:-
3.2.1 Intensifier
Intensifier pumps are called intensifiers because they use the concept of pressure
intensification or amplification to generate the desired water pressure.
If you apply pressure to one side of a cylinder and the other side of the cylinder is the
same surface area, the pressure on the other side will be the same. If the surface area
of the smaller side is half, then the pressure on that side will be doubled. Generally
with intensifier pumps there is a 20 times difference between the large surface area
(where the oil pressure is applied) and the small surface area (where the water
pressure is generated). The following picture shows this concep
Ultimately, there must be a restriction in the flow of water in order for the pressure to
be generated. This restriction is generated by the orifice in the cutting head. Pressure
is maintained until the orifice diameter exceeds the limits for water output of the
pump.
For very small diameter orifices, in order to maintain pressure, the pump only needs
to cycle very slowly to maintain pressure. As the orifice gets larger, the pump must
work faster to maintain pressure and water flow. If the orifice gets too large, the pump
tries to cycle too fast for the design specification. An "over stroke" situation is sensed
by the control and the pump is stopped with an error message.
If there are leaks in the water circuit between the pump and the cutting head, this can
also result in a pump "over stroke" situation. The leaks effectively rob water available
to go to the cutting head. The same as putting in too large of an orifice, the pump runs
faster to maintain pressure until it reaches its limit.
Typically, intensifiers stroke at around 50 - 60 strokes per minute when working at
full capacity
13
fig 3.2 Intensifier pump
3.2.2 Direct Drive
A direct drive pump works like a car’s engine. A motor turns a crankshaft attached to
3 or more offset pistons. As the crankshaft turns, the pistons reciprocate in their
respective cylinders, creating pressure in the water. Pressure and flow rate are
determined by how fast the motor turns the crankshaft. Direct drive pumps cycle
much faster than intensifiers, on the order of 1750 revolutions per minute. Direct
drive pumps generally are found in lower pressure applications (i.e. 55,000 pounds
per square inch and under). Maintenance on the direct drive pump tends to take longer
than an intensifier pump. Direct drive pumps can only run more than one cutting head
only if all cutting heads are cutting the same part at the same time. With an intensifier
pump, you could have cutting heads on multiple machines, cutting different parts,
cycling the various cutting heads on and off in any sequence. The intensifier pump
will need to only vary its stroke rate accordingly to maintain flow and pressure.
14
Fig 3.3 direct drive pump
3.3 Principles of water jet cutting
There are two types of water jet cutting processes; pure water cutting, in which the
cutting is performed using only an ultra-high pressure jet of clean water, and abrasive
15
water jet cutting in which an abrasive (typically garnet) is introduced into the high
pressure stream.
Pure water cutting can be employed to profile a huge variety of materials, these will
typically be 'soft' materials such as gaskets, rubber, foam & plastics. Filtered tap water
is fed into an intensifier pump where it is pressurised to (typically) 60,000psi. This
ultra-high pressure water is forced through a tiny (0.15mm) orifice jewel which is
normally manufactured from sapphire. This has the effect of focusing the beam of
water into a fine, accurate stream travelling at speeds of up to 900m/sec, capable of
accurate cutting of a wide range of soft materials.
In order to cut 'harder' materials or any material containing glass or metal, then
abrasive water jet cutting would be employed. The principles of abrasive water jet
cutting are similar to pure water jet cutting, but once the stream has passed through
the orifice it enters a carbide nozzle. Within this nozzle is a mixing chamber within
which a partial vacuum is created as the water passes through. Garnet is introduced
under gravity into the nozzle and the partial vacuum within the mixing chamber has
the effect of dragging the abrasive into the water stream to create a highly abrasive
cutting jet. Abrasive cutting would typically be used on materials such as stainless
steel, aluminium, stone, ceramics & composite materials.
Fig 3.4 mouth piece of jet
In both processes the head is controlled by a CNC controller, this offering great
accuracy and repeatability. The CNC controller is programmed by first drawing the
part to be manufactured using proprietary software, and then converting this drawing
into a G code format – CNC language.
16
Fig 3.5 vertical water jet
Water jet cutting is a cold grinding or cutting process. It combines the advantages of
laser – precision – with those of water: water jet cutting is thermoneutral. In addition
to laser cutting, water jet cutting is becoming increasingly important in Switzerland
and Germany. No thermal stresses occur with water jet cutting. The microstructure of
the material and the material strength remain. There are no cures, distortions, dripping
slag, melting or toxic gases.
In all processes, the cutting heads with the focusing nozzles are integrated in a
guiding machine (robot, 2D or 3D portal). The controlled CNC axes enable 2D, 2.5D
or 3D cutting processes. These processes can cut almost all materials – hard like steel
and glass, but also fragile and extremely soft materials – without stress forces. Water
jet cutting has three principles: the pure water jet principle “WJ”, the abrasive water
jet principle “AW” and the suspension jet principle, which is still at development
stage.
3.3.1 Water jet cutting with pure water:-
17
With pure water jet cutting “WJ”, a pure water jet with a diameter of 0.1 mm cuts the
material at up to three times the speed of sound (at speeds of up to 200 m/min). These
materials include textiles, elastomers, fibers, thin plastics, food, paper, cardboard,
leather, thermoplastic materials or food. The water is pressurized to 1,000–6,000 bar
(standard approximately 3,800 bar). After flowing through a high-pressure needle
valve, the water enters a 200 mm long and 3 mm in diameter wide collimation tube
(calming section). It is then pressurized by a water nozzle or a dynamic pressure
nozzle and accelerated. The jet speed varies according to geometry and pressure. The
small diameter of the water nozzle produces a very high local energy density, which
remains constant on a relatively long section in the direction of the water jet and cuts
cleanly and accurately when hitting the material.
Fig3.6 half section view of water jet
18
3.3.2 Water jet cutting with abrasives:-
With abrasive water jet cutting, compact and hard materials such as metals (including
steel), hard stone, glass (including bullet-proof glass) and ceramic are separated.
Before the concentrated jet of water hits the material, a cutting material of the finest
grain size (abrasive) is added in the required dose in a mixing chamber, which ensures
micro cutting. The water serves as an accelerator for the abrasive particles and hits the
material with an impact speed of 800 m/s, thereby removing it with precision. Until
the water jet is produced, abrasive water jet cutting is identical to pure water jet
cutting. The difference is that the pure water jet is no longer used just for cutting, but
as a carrier material for the abrasive particles. The pure water jet flows into a mixing
chamber, into which the abrasive particles are then introduced. At the end of the
mixing chamber is the focusing tube, in which the abrasive grains in the water jet are
accelerated and confined to a specific cross-section.
19
3.3.3 Water jet cutting with suspension jet
With the suspension jet principle or water abrasive suspension jet cutting, a pre-
prepared mixture of abrasive particles and water is discharged under high pressure
from a cutting nozzle. However, the abrasive agent is not added at the nozzle but is
pressurized under the exclusion of air. Therefore, a water-abrasive mixture (a
suspension) is expelled from the cutting nozzle under high pressure. This enables
higher cutting performance, allows greater thicknesses and almost all materials to be
cut. However, there is a delay in the start and stop of the cutting operation, since the
abrasive feed cannot be switched on and off as rapidly as in injection cutting. This is
one disadvantage when high-precision cutting is required. The wear on the valves and
nozzles is also much larger and attainable pressures are smaller. Therefore, this
principle is only seldom used on an industrial scale.
Fig 3.7 suspension jet
20
3.4 PARTS OF WATER JET CUTTER:-
3.4.1. Electric motor and hydraulic pump
The electric motor and hydraulic pump (number 1 in picture above) create the oil
pressure needed for the oil side of the intensifier. This assembly is normally in the
lower portion of the pump cabinet. The electric motor and pump are rated in HP (or
kW for metric). Typical pump sizes are 30 HP, 50 HP, 75 HP, 100 HP and 150 HP As
discussed in the previous chapter, each pump will have an associated water output
volume (gallons per minute) and pressure (psi).
Again it is important to remember that HP is not necessarily an indication of pressure.
A 150 HP pump doesn’t necessarily create more pressure than a 50 HP pump.
Horsepower is more directly related to water output, since more HP will be needed to
create enough power to move the piston/plunger assembly in the intensifier at the
required stroke rate.
Fig3.8 Intensifier pump cabinet (150 HP)
21
3.4.2. Directional control valves
One of the most important considerations in any fluid power system is control. If
control components are not properly selected, the entire system does not function as
required. In fluid power, controlling elements are called valves. There are three types
of valves: 1. Directional control valves (DCVs): They determine the path through
which a fluid transverses a given circuit. Pressure control valves: They protect the
system against overpressure, which may occur due to a sudden surge as valves open
or close or due to an increase in fluid demand. 2. Flow control valves: Shock
absorbers are hydraulic devices designed to smooth out pressure surges and to
dampen hydraulic shock. In addition, the fluid flow rate must be controlled in various
lines of a hydraulic circuit. For example, the control of actuator speeds can be
accomplished through use of flow control valves. Non-compensated flow control
valves are used where precise speed control is not required because the flow rate
varies with pressure drop across a flow control valve. It is important to know the
primary function and operation of various types of control components not only for
good functioning of a system, but also for discovering innovative methods to improve
the fluid power system for a given application. 1.2Directional Control Valves A valve
is a device that receives an external signal (mechanical, fluid pilot signal, electrical or
electronics) to release, stop or redirect the fluid that flows through it. The function of
a DCV is to control the direction of fluid flow in any hydraulic system. A DCV does
this by changing the position of internal movable parts. To be more specific, a DCV is
mainly required for the following purposes: To start, stop, accelerate, decelerate and
change the direction of motion of a hydraulic actuator. To permit the free flow from
the pump to the reservoir at low pressure when the pump’s delivery is not needed into
the system. To vent the relief valve by either electrical or mechanical control. To
isolate certain branch of a circuit. 2 Any valve contains ports that are external
openings through which a fluid can enter and exit via connecting pipelines. The
number of ports on a DCV is identified using the term “way.” Thus, a valve with four
ports is a four-way valve A DCV consists of a valve body or valve housing and a
valve mechanism usually mounted on a sub-plate. The ports of a sub-plate are
threaded to hold the tube fittings which connect the valve to the fluid conductor lines.
The valve mechanism directs the fluid to selected output ports or stops the fluid from
22
passing through the valve. DCVs can be classified based on fluid path, design
characteristics, control methods and construction
Fig 3.9 Directional Control Valve
3.4.3. Intensifier
The intensifier proper (3 in Figures 4 and 2) consists of the hydraulic cylinder (4),
high pressure cylinders (7), and check valves (8) and end caps (9). Not visible from
the outside are the piston and plunger.
Fig 3.10 Intensifier
23
3.4.4. Hydraulic cylinder
The hydraulic cylinder (4 in Figures 2 and 5) houses the piston and is the area where
the hydraulic oil does its work. The directional control valves control the flow of oil
into and out of each side of the hydraulic cylinder.
At each end of the hydraulic cylinder is an end plate that is used to connect the
hydraulic cylinder to the high pressure cylinder. The two end plates for the hydraulic
cylinder are connected and pulled tightly in place with 4 tie rods and bolts.
Fig 3.11 Hydraulic cylinder
3.4.5. Piston
The piston (number 5 in Figures 2 and 6) is the larger diameter cylindrical part
located within the hydraulic cylinder (4 in Figures 2 and 5). The piston effectively
splits the hydraulic cylinder into a left side and a right side. Oil cannot pass from one
side to the other past the piston. It must exit and enter the hydraulic cylinder through
the hoses attached to the directional control valve. The hydraulic oil pressure is
exerted onto either side of the piston in an alternating fashion so that a back-and-forth
movement of the piston and plunger assembly is generated.
24
Fig 3.12 Piston (5) and plunger (6) assembly
3.4.6. Plunger
The plungers (6 in Figure 7) are the two smaller diameter shafts that are connected to
each side of the piston. The attachment point is inside of the hydraulic cylinder. The
other ends of the plungers extend into the left and right high pressure cylinders. Seals
are placed around the plunger shaft to keep oil from seeping into the water side of the
pump, and vice versa. The plungers are made out of either stainless steel, or, more
recently, ceramic. Ceramic is used because of its ability to handle heat and high
pressure with little thermal expansion.
Fig 3.13 Ceramic plunger
25
3.4.7. High pressure cylinder
The two high pressure cylinders (7 in Figures 8 and 2) are where the water is
pressurized. They are usually referred to as "left hand side" and "right hand side." The
high pressure cylinders are machined out of very thick stainless steel and treated in
order to withstand the extreme pressures they are put under on a continual, cyclical
basis.
Fig 3.14 High pressure cylinder (7)
3.4.8. Check valve
There is one check valve (number 8 in Figures 10 and 8) at the end of each high
pressure cylinder at the end opposite from the hydraulic cylinder. The check valve
allows fresh water to enter the high pressure cylinder and high pressure water to exit
the intensifier. The check valve is designed to only let water flow in one direction.
Fresh water comes in though channels machined in the sides and exits through one or
more holes in the face of the valve. Various seals, poppets and springs are used to
maintain this water flow. Over several hundred hours these components will wear,
allowing pressurized water to flow out the water inlet path, or allowing pressurized
water to seep back into the high pressure cylinder. The symptoms and diagnosis of
these various situations will be discussed later in the "Maintenance" chapter.
26
Fig 3.15 View of upper portion of intensifier cabinet
Fig 3.16 Check Valve Body cross-section
27
3.4.9. End Cap
The end cap (number 9 in Figures 11 and 2) is either a cylindrical or square item. The
cylindrical version screws onto the output end of the high pressure cylinder. The
square type is held in place with tie rods and bolts. The end cap has a hole in the
center for the check valve and outlet body. It will also have a connection point for the
incoming fresh water. The water flows through holes machined through the cap to line
up with inlet holes in the check valve
Fig 3.17 fillets caps
28
3.4.10. High pressure tubing
High pressure 304 or 316 stainless steel tubing (number 10 in Figure 11) is attached to
the outlet of each check valve. Common outer diameters are 0.25", 0.313", 0.375" and
0.563". Inner diameters range from 0.062" to 0.312". There is usually a flexible
protective covering around the tube.
The high pressure tubing from the left hand high pressure cylinder will join together
at some point with the high pressure tubing from the right hand cylinder. The high
pressure tubing carries the pressurized water to the pressure attenuator. Additional
high pressure tubing will channel the high pressure water to the cutting head.
The length, number of bends and other obstructions to flow (e.g. hand valves) in the
high pressure tubing path must be taken into consideration when designing a high
pressure water jet system. Pressure will drop with each bend in the tubing. Also, as
the distance between the pump and the cutting head increases, internal friction of the
water as it drags against the inner walls will generate heat resulting in a loss of water
pressure. This topic will be discussed in more detail in the Chapter 5 "Pressure Drop
in Tubing."
3.4.11. Pressure attenuator
The pressure attenuator (number 11 in Figures 13 and 2) smoothest out variations in
pressure after the high pressure water has exited the intensifier. With each reversal of
cycle of the intensifier, there is a slight delay in the increase of water pressure in the
opposite high pressure cylinder. This delay is due to: 1) reversal of motion where
instantaneous velocity at the end of the stroke equals zero, and 2) mechanical delays
of reversal. All of these factors can result in a drop in water pressure. Some
manufacturers do use proprietary technology to reduce this pressure drop, which we
suggest you investigate when selecting a pump. Generally, if a 50 HP pump can
sustain a 0.014" orifice at 60,000 psi continuous operating pressure, the implication is
that this hydraulic pressure drop challenge will have been addressed.
Figure 14 shows the pressure fluctuations in the high pressure water line prior to the
pressure accumulator. This shows a pressure change from high to low of almost
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22,000 psi. So, for a 60,000 psi system, the high pressure water would be going from
60,000 psi to 40,000 psi after every stroke of the intensifier.
If this pressure fluctuation were not smoothed out by the pressure attenuator, cutting
results at the work piece would be undesirable. There would be a significant line in
the part with every stroke of the intensifier. Recall that any change in pressure results
in a change in speed of the water jet stream at the cutting head. This change in speed
changes the speed at which the abrasive particles are moving and, therefore, the
amount of force they will impact on the work piece. Lower pressure leads to less
speed of the water which leads to less force of the abrasive which leads to slower
cutting, or rougher edge quality.
Fortunately the pressure attenuator smoothest out these pressure spikes so that the
water at the cutting head maintains a steady pressure, speed and cutting power
Fig3.18 Pressure Attenuator
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Fig3.19 Pressure fluctuation prior to accumulator
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3.4.12. Inlet water
Prior to entering the pump cabinet, water may have to be treated to get the water
within the water jet manufacturer’s specifications. Within the pump cabinet, usually
in the lower portion, the water will typically go through one or more final filters just
prior to entering the intensifier (number 12 in Figures 15 and 2).
The inlet water must be able to maintain a specified flow rate and pressure to ensure
that the intensifier receives enough water. Incoming water must also meet certain
requirements with respect to Total Dissolved Solids (TDS), pH, organic matter,
temperature, etc. Poor water quality will result in drastically reduced high pressure
component life (i.e. anything the high pressure water comes in contact with).
Different pump manufacturers require different inlet water pressures, with some
needing as little as 30 psi, and others mandating a water pressure booster pump to
maintain 100 psi. Water quality will be discussed in more detail in the chapter 4
"Water QUILITY
Fig 3.20 water inlet system
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3.5 Controls and PLC
The controls and PLC (not pictured) control the valves in the hydraulic circuit to
determine the pressure and flow of the hydraulic oil to and from the intensifier.
Various sensor and proximity switches can also be integrated into the controls to
monitor the entire pump to verify things like stroke rate, oil temperature and pressure,
inlet water pressure and flow rate and more. This capability makes working with and
troubleshooting the modern day intensifier much easier.
3.5.1 On-Off Valve
The pneumatic On-Off valve controls the flow of water to the cutting head. The On-
Off valve at the cutting is "normally closed." That is, when there is no compressed air
supplied to the On-Off valve, a needle fits tightly against a seat to stop any high
pressure water from getting to the cutting head. When compressed air is supplied to
the On-Off valve (i.e. "tool on" command from the control), the needle is forced up
from its seating location and the high pressure water can flow through the orifice to
the cutting head.
In, or near, the high pressure pump cabinet is another On-Off valve that works in
tandem with the On-Off valve at the cutting head. The On-Off valve in the pump is
typically called the Safety Relief valve. This Safety Relief valve in the pump is
"normally open." This valve will stay open when there is no air supplied to it. When
the On-Off valve at the cutting head closes ("tool off" command by control or no
power to the system), the Safety Relief valve in the pump will open, relieving all
water pressure from the high pressure tubing. When the "tool on" command is issued
by the control, the Safety Relief valve closes so that all high pressure water will go to
the cutting head. Note, not all manufacturers of new pumps have the Safety Relief
valve as standard. We strongly suggest you ask your pump manufacturer if they
supply this standard, and when it is activated. Again, some pump manufacturers will
only activate the Safety Valve when an E-Stop is pressed; when the pump stops, high
pressure lines are still pressurized.
Both of these On-Off valves must be in good working order to protect against
accidental high pressure water discharge at the cutting head that could severely injure
someone working on or near the cutting head or any of the high pressure lines.
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Periodic replacement of the needle, seat and associated parts is required to maintain
these valves.
Fig 3.21 on/off valve
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3.6 Abrasive feeding system
3.6.1 Pressurized Bulk hopper:-
Abrasive is transported via tubing and pressure from a large bulk hopper located near
the water jet cutting system to a mini-hopper near the cutting head. Bulk hoppers will
normally hold anywhere from several hundred pounds of abrasive to 2200 pounds. If
you are cutting with one head and 1.4 pounds per minute of abrasive, then you are
consuming about 84 pounds per hour. An 1100 pound hopper would last about 13
hours of operation. This would mean that the machine could run for well over a shift
before it needed to be refilled. Most water jets are provided with approximately 600
pound hoppers, which would equate to about 7 hours of operation. So, at least once
during an 8 hour shift the hopper would need to be reloaded. The costs associated
with the additional downtime over the course of a year should be evaluated.
Fig 3.22 bulk hopper
3.6.2 Mini-hopper
A mini-hopper is typically mounted near and above the cutting head. Most of these
mini-hoppers allow for a gravity feed of abrasive down to the cutting head. Many
mini-hoppers control the amount of abrasive that can go down to the cutting head with
the use of a slide with different size holes in it. The operator can change the position
of the slide to change the amount of abrasive to the cutting head.
A recent advance in technology is remote CNC-control of the amount of abrasive
released from the mini-hopper. Having this capability allows for optimum feeding of
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abrasive to the cutting head in relation to the water pressure at the pump for the
following desirable capabilities:
Piercing of fragile materials like glass or stone. Typically a lower
water pressure will be used with a smaller amount of abrasive
Changing abrasive amount for different abrasive nozzle sizes to
optimize part cost. This can be done automatically if the mini
hopper is set up to do this.
Fig 3.23 abrasive material feeding
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CHAPTER 4
4.1 WATER QUALITY:-
4.1.1 Overview
This chapter will discuss water quality requirements for high pressure water jet
cutting and why it is crucial to maintain proper water quality.
Note: See "Recommendation for water treatment" at the end of this chapter for a
potential solution to everything you are about to read in this chapter about water
treatment.
4.1.2 Water specifications
Every manufacturer has specific requirements for water quality. Check with the
manufacturer to get the specifications for your particular machine.
The water supplied to the intensifier is critical to water jet cutting due to its direct
influence on the service life of the equipment components such as check valves, seals
and orifices. A high concentration of Total Dissolved Solids (TDS) causes accelerated
wear of any components that come in contact with the high pressure water because of
the increased abrasiveness of the water from the TDS.
As part of the installation planning, a water quality analysis should be performed by a
commercial company that specializes in water conditioning equipment. The minimum
information that should be supplied by this analysis is TDS, silica content and pH
value. Companies like Culligan can perform these tests, or you can search "water
quality testing" on the internet.
Inlet water should be treated for either the removal of hardness of the reduction of
TDS. Water softening is an ion exchange process that removes scale forming minerals
such as calcium. TDS reduction can be accomplished with either deionization (DI) or
reverse osmosis equipment. Generally, DI or RO provides better component life than
water softening.
37
A water purification supplier should be consulted to supply the most suitable
equipment for special conditions. It might be a good idea to ask any company that you
are considering using if they have supplied systems for any other high pressure water
jet cutting systems and check their references.
The best treatment process for a specific application is a function of the original water
quality and the desired service life of the affected components. Sixty to 70 ppm of
TDS is optimum. Any water treatment producing TDS content of less than 0.5 part
per million (ppm) should be avoided since the aggressiveness of such purified water
will damage pump components.
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4.2 Water treatment guidelines
Criteria Values Recommended
Treatment
Total Dissolved
Solids (TDS)
Low TDS (<100
ppm)
Moderate TDS (100
- 200 ppm)
High TDS (>200
ppm)
Good water, requires only
softening
Can be treated by
softening, DI or RO
Poor water, should be
treated with RO or DI
Silica Content High content (>15
ppm)
Dual Bed Strong Base DI
pH Value Treated water must
have a value of 6 - 8
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4.3 Suspended solids
In addition to the treatment described above, the water must be filtered for the
removal of suspended solids. Different manufacturers supply differently sized final
filters for this purpose, typically down to 0.45 nominal. See "Recommendation for
water treatment" at the end of this chapter for an alternative to this.
Water supply
The initial water supply should be at least 5 gallons per minute at 40 pounds per
square inch. The water may be boosted by a small pump to the 80 psi required by
most intensifiers. Some intensifiers do not require pressure boosters, requiring only 30
psi for the incoming water. This removes a potential failure point from the system.
Hydraulic Oil Cooling
Intensifier pumps have hydraulic oil that must be cooled. Typically there are three
options:
1. Water-Cooled through a heat exchanger
2. Air-Over-Oil Cooler
3. Closed-Loop Chiller
4.
4.3.1 Heat exchanger - For water cooled pumps
1. A heat exchanger is primarily used for cooling the hydraulic fluid of the
intensifier pump. Typically the hydraulic oil temperature must be kept below
120° F (49° C). The heat exchanger will require a consistent water flow of 0 to
8 gpm (0 to 30 liters per minute) at an inlet temperature not exceeding 70° F in
order to keep the hydraulic fluid at the proper temperature. Actual volume of
water will depend on the pump selected. As many pumps are thermostatically
controlled, when the pump is cool, it may be that no water is required.
2. This cooling water must go to drain. The cost of this water must be balanced
against the costs of the other two cooling options (air-over-oil and chiller),
which would not have any water going down the drain.
3. Public utility water is usually acceptable for cooling purposes. In situations
where the water contains heavy mineral deposits, the exchanger tubes may
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eventually become restricted by particle buildup. If this is a chronic problem,
pre-filtration and/or water softening may be necessary.
4. Depending upon plant setup, ambient temperature can also be a factor in
cooling the hydraulic fluid. Additional cooling may be required if the
intensifier and/or heat exchanger is confined to a small, high-temperature
space.
Fig 4.1 heat exchanger
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4.3.2. Air-Over-Oil Cooler
Some pumps will use an oil-air cooler to remove heat from the hydraulic oil, so no
heat exchanger is required. In the summer, the unit can be vented outside the building
to remove the heat from the building. In the winter it can be vented inside the building
to help out with heating the building.
Fig 4.2 oil cooler
4.3.3. Chiller
A chiller can be used to re-circulate the cooling water that is used by the intensifier's
heat exchanger. It cools the water and then sends it through the heat exchanger again,
creating a closed loop. A chiller is most effective in worth considering in a few
situations in particular:
Warmer climates where the efficiency of the heat exchanger may be reduce
Facilities that cannot send any water to a drain,
Parts of the country where there is a water shortage, or if the cost of water is high,
because a 50 HP pump can use up to 5 gpm for cooling the hydraulics.
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The chiller will only reuse the cooling water; you will still be putting approximately 1
gpm with a 50 hp pump of fresh water through the cutting head, which will not be
reused with the chiller.
Incoming water for the intensifier should also be maintained at 70° F (21° C) or
cooler for best high pressure seal life. If this temperature cannot be maintained, then
the chiller can also be used for this water.
Fig 4.3 chiller
Water circuit options
Water circuit options
Following are 4 different scenarios for the water flow through a water jet cutting
system.
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Option 1 - Heat exchanger in pump, all water runs to a drain.
fig 4.4 Heat exchanger in pump, all water runs to a drain.
Option 2 - Air-Over-Oil cooler
fig 4.5 Air-Over-Oil cooler
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Option 3 - Chiller and heat exchanger. Water for heat exchanger re-circulates; used
water from cutting runs to drain.
Fig4.6 water from cutting runs to drain.
Option 4 - Heat exchanger, chiller and WRS-3000 water recycling unit. No water to
drain. Only water required is make-up water to replace evaporation and spillage.
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4.4 Recommendation for water treatment
WARD Jet has found that the use of a good quality water softener in conjunction with
a 0.2 absolute final filter to be successful for treatment of water for the intensifier.
This setup can be used as long as the water from the cutting tank is not being recycled
for use through the intensifier. In the worst case, if seal life does not seem to be living
up to expectations, then a DI or RO system can be installed
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4.4.1 Benefits of Water jet Cutting
As one of the fastest growing machine tool industries, water jet cutting has proven to
save time and money on countless applications such as metal cutting and stone
cutting. See the advantages of water jet cutting and view our photo album of different
uses for the tool. Whether it's cutting sheet metal, titanium, granite, marble, or steel -
water jet might be the answer for you.
Benefits of Water jet Cutting
Let's Take a Look... Water jet cutting is best described as an accelerated erosion
process that we are controlling. For this reason, water jet can cut or erode through
virtually any material known, making it one of the most versatile machines available.
As one of the fastest growing machine tool industries, water jet cutting has proven to
save time and money on countless applications. Please take a look at the advantages
below to see if water jet could be for you.
Tolerances
Tolerances tighter than +/- 0.005" are achievable,
especially in thinner materials such as 1" stainless
steel. However, high tolerances come with a price,
sometimes up to 500% higher than if the same part
had been specified with a tolerance of +/- 0.015".
By being more flexible with tolerances, prices will plummet as cutting speeds
increase. Water jet cutting has the ability to vary tolerances in different locations on a
part, ensuring the best pricing and quality.
Thickness And Kerf
Materials ranging from 10" stainless steel to
0.010" acrylics can be cut by water jet, making it a
very versatile tool. Stacking of very thin materials
to increase productivity is possible. Kerf ranges
from 0.020" to 0.050".
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Taper and Edge Finish
Taper and edge finish are directly related to cut speed.
The greater the speed, the more taper and the coarser
the edge finish. As the water jet slows down, taper can
be eliminated and the finish of about 120 achieved.
Again, slower means an increase in time...and price.
For a finer edge finish, use a finer abrasive.
No Heat Affected Zone (HAZ)
Water jet cutting is a natural erosion process involving no
chemicals or heat. Because of this, warping and distortion
typically associated with laser, plasma and oxy-fuel
cutting is eliminated, therefore minimizing the need for
secondary processing.
Nesting And Common Line Cutting
Unlike laser, plasma and oxy-fuel cutting, water jet
lends itself to common line cutting. WARDJet offers
optional state-of-the-art nesting software, allowing you
to nest multiple shapes together and cut them with
multiple heads. Tracking of remnants and nesting into
these odd shapes later, helps save precious material and can contribute toward
reducing your operating costs.
Cutting Speeds
The speed at which the water jet can cut through material will vary based on a variety
of parameters. In the charts below you can see that the orifice/nozzle combination you
select will have an influence on your cut speed. Generally when cutting with a single
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head and a 50 hp pump the chart with the 14/40 orifice/nozzle combination is the
closest guide for cut speed. When cutting with two heads and a 50 hp pump use the
chart with the 10/30 orifice/nozzle combination to indicate the cutting speed of each
head.
After selecting the correct chart find the material and the thickness that you will be
cutting. This will then give you an idea of your straight line cutting speed based on
the quality of edge finish and tolerance you need for your parts. These cutting speeds
are only a guide to estimate cutting speeds achievable. We recommend that test
cutting is done to determine actual feed rates on different materials and thicknesses.
4.5 Water jet in Any Industry
The versatility of the water jet allows it to be used in nearly every industry. There are
many different materials that the water jet can cut. Some of them have unique
characteristics that require special attention when cutting. As you can see in the chart
below each material you cut will have some unique characteristics that have to be
taken into account.
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The information below explains some of the cutting techniques we've used when
cutting these materials. We recognize that there are many materials not listed so if
you have a specific question about your material feel free to contact us at (330) 677-
9100.
4.5.1Alloys
Inconel, Hastalloy, Wasp alloy, Titanium, Aluminum, Stainless etc. No heat effected
zone or change in the molecular structure occurs in the alloy material. There is no
distortion as seen with typical heat cutting methods. Generally, cutting with water jet
costs less than traditional machining or cutting methods. In many cases, no secondary
removal of slag or damaged material is necessary, and minimal to no burring is seen.
4.5.2Steels
Water jet is not always the most cost effective method to cut steels. As a rule, if the
finished product is presently being cut using laser, plasma or oxyfuel, and no
secondary work is needed to the part after being cut, it is unlikely water jet will be an
economical solution. However, as soon as any secondary work, closer tolerances or
removal of the Heat Affected Zone (HAZ) is needed, water jet is probably the
solution. With the use of the WARD (Water jet Abrasive Recycling Dispenser)
companies are able to reduce their operating cost substantially, reducing the gap
between laser and water jet cutting. In many cases, water jet now costs less than laser!
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4.5.3Laminates
Water jet, in most cases, does not see any difference between laminated materials -
e.g. acrylic, aluminum, stainless and honeycomb section all laminated as one. Many
aircraft parts consist of laminated materials where water jet is the only solution.
4.5.4Composites
many composites are very difficult to machine as the cutting tool tips 'gum' up and
quickly becomes inefficient. Water jet has no gumming at all and can leave a good
clean surface requiring no additional work.
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4.5.5Plastics/Acrylics
It is possible to not only cut these materials effortlessly, but also drill start holes using
specialized low-pressure options available with certain systems.
4.5.6Rubber
Depending on the durometer value, rubber can be cut with water only or with
abrasive. Tests will quickly reveal what the best option is for your application.
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4.5.7Gaskets
By using water jet for cutting gaskets, it is possible to automatically nest various sized
and shaped gaskets on one sheet effortlessly. There is no longer any need for stacks of
dies. Software will keep track of all remnant sheets allowing off cuts to be put back
into inventory and used for smaller parts. Specialized software is available to track
materials through the entire process.
4.5.8Fiberglass
When cutting materials that are typically associated with hazardous fine airborne
materials, water jet is an ideal solution. Particles and materials removed are
transported by the water away from the surface into the tank, reducing this risk and
hazard.
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4.5.9Glass
Intricate cutting and shaping of glass is easy with water jet. The water jet can
generally drill all its own start holes, making it a highly versatile tool. Glass from
1/32" to 10" thick can be cut, even when laminated in multiple layers.
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CHAPTER 4
CONCLUSION:-
As a conclusion, the experiment that have been carried out were successful, even
though the data collected are a little bit difference compared to the theoretical value.
The difference between the theoretical value and the actual value may mainly due to
human and servicing factors such as parallax error. This error occur during observer
captured the value of the water level. Besides that, error may occur during adjusting
the level gauge to point at the white line on the side of the weight pan. Other than that,
it also maybe because of the water valve. This error may occur because the water
valve was not completely close during collecting the water. This may affect the time
taken for the water to be collected. There are a lot of possibilities for the experiment
will having an error. Therefore, the recommendation to overcome the error is ensure
that the position of the observer’s eye must be 90° perpendicular to the reading or the
position. Then, ensure that the apparatus functioning perfectly in order to get an
accurate result.
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REFERENCE
1.http://www.cee.mtu.edu/~dwatkins/ce3600_labs/impact_of_jet.pdf
2. http://www.eng.ucy.ac.cy/EFM/Manual/HM%2015008/HM15008E-ln.pdf
3.http://staff.fit.ac.cy/eng.fm/classes/amee202/Fluids%20Lab%20Impact%20of%20a
%20Jet.pdf
4. WIKIPEDIA
5. http://www.wardjet.com/water jet-university
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