As new
technologies move on, there are many approaches, inventions and solutions for
making something more efficent but cheaper, I am asure that there are several
or even dozens solutions what make energy of wind efficient, renewable and most
of that all, useful.
Wind is form of solar energy. The term „wind energy“ describes the process by
which the wind is used to generate mechanical power or electricity. Winds
are caused by the uneven heating of the atmosphere by the sun, the
irregularities of the earth's surface, and rotation of the earth. Wind flow
patterns are modified by the earth's terrain, bodies of water, and vegetative
cover. There are specialized turbines that convert kinetic energy of wind into
a mechanical raw power. A wind turbine is constituted of three or two
propeller-like blades called rotor. The rotor is attached at the top. As the wind blows it spins the rotor. As the rotor spins the energy of
the movement of the propellers gives power to a generator. There are some
magnets and a lot of copper wire inside the generator that make electricity.
One wind turbine can generate enough electricity for a single house. As they
are higher, they are better for producing more wind energy. It is very high and
expensive investment, but it is one of the most efficient ways od producing
energy by itself. Turbine is made of blade(rotor), drivetrain, “tower”.
Its all about pressure of wind and about heights in
which rotor operates. Wind is clear source of renewable energy, and that is one
of the main advantages of wind energy. Mass production and technology advances are making turbines cheaper, and many governments offer tax incentives to spur wind-energy development. It is one of the most
reliable sources of energy and is booming more and more. A wind turbine creates
reliable, cost-effective, pollution free energy.
As years goes ahead will be seeing more and more types of this free-cost energy
that will make our future productive even more and so even much greener in
every part of it.
I support this type of energy and I hope it will spread even more.
četvrtak, 11. srpnja 2013.
ponedjeljak, 8. srpnja 2013.
Maintenance in engineering
As
part in field of mechanical engineering maintenance doesnt sound so powerful
like mechanical design, constructions or manufacturing but it has very
important role for every of this part and its link to everyone of them.
Main role of maintenance engineering is to make some machine or some element that has role or is link to some other element durable and long lasting. Product lifecycle must be long and with dowsizing curve of maintenance product. Therefore we must observate all parameters in product and around product and make them more efficent, secure and properly prepared for everyday role of that product.
Main objectives of maintenance engineering are:
-provide the required level of reliability
-minimize maintenance costs due to failures caused by teh. systems, leading to losses in production
-restrict and slow obsolescence of technical systems
-propose and implement modernization and modifications in order to improve performance and extend product life
-ensure safe operation
-ergonomic design of the workplace
-monitor and improve the safety equipment in order to reduce and eliminate adverse effects on the environment
Every product has its own lifecyle and there is no machine or product that will never be „ill“.
Its about making product more efficent, more productive and more longlasting.
To make that happen there are many fields of maintenace engineering that help us to do so.
Corrective maintenance is based on elimination of damage and failures after they occur.
Before we kick on about corrective maintenance we first must define meaning of word damage and failure.
Damage is change of state of the system or its components that are not bothering to function of system, but it can turn into a failure.
Failure is change of the state of the system or its components, which obstructs or impedes the normal functioning of the system.
Advantage of corrective maintenance in the better use of spare parts and components, maintenance before the failure, construction of reliable components of technical systems.
Preventive maintenance is based on the performance of a series of interventions by its plans before the injury occurs or failures.
Advantages of preventive maintenance are in reducing time failures, plan and prepare is in advance.
It defines many operations what are in purpose of fulltime supervision and to take certain actions to reduce defects and failures.
CBM (Condition Based Maintenance) The basic approach to CBM depends on to control the level of reliability is reduced to the continuous use of components and technical systems as long as the actual level of confidence within the limits determined values.
Advantages are increased security, increased the output (quantity) of the production system, increased the availability and reduce maintenance operations, improved quality of products.
There are different approaches of maintenance and everyone of them is defined in different way for a different operation or type of operation. All type of maintenances have own advantages and disadvantages. In most ways and cases type of maintenance that will be using is defined of properties of elements and machines that will be used in some circumstances or specific situations.
Main role of maintenance engineering is to make some machine or some element that has role or is link to some other element durable and long lasting. Product lifecycle must be long and with dowsizing curve of maintenance product. Therefore we must observate all parameters in product and around product and make them more efficent, secure and properly prepared for everyday role of that product.
Main objectives of maintenance engineering are:
-provide the required level of reliability
-minimize maintenance costs due to failures caused by teh. systems, leading to losses in production
-restrict and slow obsolescence of technical systems
-propose and implement modernization and modifications in order to improve performance and extend product life
-ensure safe operation
-ergonomic design of the workplace
-monitor and improve the safety equipment in order to reduce and eliminate adverse effects on the environment
Every product has its own lifecyle and there is no machine or product that will never be „ill“.
Its about making product more efficent, more productive and more longlasting.
To make that happen there are many fields of maintenace engineering that help us to do so.
Corrective maintenance is based on elimination of damage and failures after they occur.
Before we kick on about corrective maintenance we first must define meaning of word damage and failure.
Damage is change of state of the system or its components that are not bothering to function of system, but it can turn into a failure.
Failure is change of the state of the system or its components, which obstructs or impedes the normal functioning of the system.
Advantage of corrective maintenance in the better use of spare parts and components, maintenance before the failure, construction of reliable components of technical systems.
Preventive maintenance is based on the performance of a series of interventions by its plans before the injury occurs or failures.
Advantages of preventive maintenance are in reducing time failures, plan and prepare is in advance.
It defines many operations what are in purpose of fulltime supervision and to take certain actions to reduce defects and failures.
CBM (Condition Based Maintenance) The basic approach to CBM depends on to control the level of reliability is reduced to the continuous use of components and technical systems as long as the actual level of confidence within the limits determined values.
Advantages are increased security, increased the output (quantity) of the production system, increased the availability and reduce maintenance operations, improved quality of products.
There are different approaches of maintenance and everyone of them is defined in different way for a different operation or type of operation. All type of maintenances have own advantages and disadvantages. In most ways and cases type of maintenance that will be using is defined of properties of elements and machines that will be used in some circumstances or specific situations.
Turbocharger vs. Mechanical compressor
We have a number of ways with which we can
increase the power of the engine, as you add more air and fuel into the
cylinders in the combustion process. Another option is to add more cylinders or
increase existing cylinders, these changes are not always possible or very
simple. The second and the most easiest way is using a turbocharger.
Turbocharger, turbine turbocharger or whatever you like to call it.
Turbocharger is actually the correct name because it is a device that consists
of a turbine and compressor parts. When they say turbines, experts in the field
would understand that we are talking about the exhaust gases of which energy is
converted into mechanical energy. In the auto industry, there are several ways
of so-called "boost". The
engine burns a mixture of air and fuel, the air entering the engine through the
intake manifold of the engine pulled from the surrounding atmosphere pressure
difference created by the engine. In order to maximize the amount of air forces
we use methods such as superchargers and turbochargers and so. For people who can
not deal with the car topics the word
'turbo' is over the past decade mainly associated with diesel engines. The
so-called "turbo" era ended in the late 90s and since then until
today turbo really is what the vast majority of cases suggests that it is a
diesel engine. The first thing we need to clarify the difference between the
meanings of words turbocharger and compressor (mechanical compressor). Turbo
compressor (turbocharger) are commonly referred to as just the turbo, and english
literature is a term used "turbocharger", while the mechanical
compressor can still call compressor (using the name Mercedes Kompressor),
charger (G Charger - VW) while in england literature mechanical compressors
called "supercharger". There are rotary wing compressors, root blower,
compressor, screw compressor (G-compressor), turbocharger (turbocharger).
Turbocharger is not a "compressor",
but rather a classic "turbo", "turbine", turbocharger. The
turbocharger is the assembly consisting of the turbine (the device which
rotates the pressure of exhaust gases) and compressors (equipment powered
turbine and which presses intake air).
Turbocharger use energy of exhaust gases that
are thrown away and the compressor use motor power and thats why turbo is an
advantage. The lack of a turbocharger is turbo hole. It's hard to say which is
better, but it is obvious that turbocharger founded greater application.
Turbo: turbo blower, turbo, turbocharger
Compressor: mechanical compressor, supercharger
The turbines are used in power generation, aerospace
and automotive industries, and what makes it different, of course, performance
due to their different tasks, but what connects them is certainly the same
layout and working principle. In the auto industry, there are several ways of
the so-called "boost" that additional give compaction more air than a
natural pressure. The engine burns a mixture of air and fuel, the air entering
the engine through the intake manifold of the engine pulled from the
surrounding atmosphere pressure difference created by the engine.
Technology has now progressed very well. To be
effective, turbocharger must be adapted to the specification and the purpose of
the engine that is built, it is to take literally thousands of parameters. Why
use turbo instead of a mechanical compressor? All kinds of techniques for
increasing engine power have their advantages, but generally speaking, in my
opinion, especially in regard to "Performance" engines, turbocharging
is the best solution. The advantage of the atmospheric engine before turbo
engines in their simple construction and good response to openness of damper
forces. The disadvantage is the price and lag (attack power) that can be
reduced if we reduce sluggishness that weight moving parts. But compared to the
turbo assisted engines, the atmospheric engine is much harder to draw extra
power and torque. Engines with mechanical supercharger have a similar response
and give good power at all engine speeds, but they are driven directly from the
crankshaft. All in all, though you will lose something in the throttle
response, turbochargers bring huge benefits in performance, and the relatively
easy installation, reliability, and lower costs. In pursuit of power and
torque, turbo is „king“.
nedjelja, 7. srpnja 2013.
Materials for cylinders
In the wide field
of new technologies and knowledge, the regular adaptation to new
approaches to production and processing of materials for motors in motor
vehicles many elements of functional and economical operation adapt to new
technologies and strives so. Downsizing is one of the key factors in achieving
this goal, the cylinders and high tech materials that are used when creating
such. Cylinder as the element in a motor mechanism plays an important role,
serving as a supporting element or piston rod that performs the function of the
linear motion of the TDC to BDC. Large thermal expansion occurring within that
element and the material from which the cylinders are made must also be good
heat implementers. Temperatures are in the high ranges, and it is very
important to maintain an optimum temperature range in order to avoid
overheating and in order to make usable engine for longer period . New
approaches in mixture injection are making more difficult situation to cylinder
constructing and therefore gives more indication to adaptation and the
development of a certain normal and optimal lifetime motor functionality period
(most optimal does not exist, and never will be!)
There are other possibilities, but these above are actually the nearest optimal and most cost.
Machining processes that help in this are honing and turning.
Honing is an abrasive machining process that produces a precision surface on a metal workpiece by scrubbing an abrasive stone against it along a controlled path. Honing is primarily used to improve the geometric form of a surface, but may also improve the surface texture.
Turning is a machining process in which a cutting tool, typically a non-rotary tool bit, describes a helical toolpath by moving more or less linearly while the workpiece rotates. The tool's axes of movement may be literally a straight line, or they may be along some set of curves or angles, but they are essentially linear (in the nonmathematical sense). Usually the term "turning" is reserved for the generation of external surfaces by this cutting action, whereas this same essential cutting action when applied to internal surfaces (that is, holes, of one kind or another) is called "boring". Thus the phrase "turning and boring" categorizes the larger family of (essentially similar) processes. The cutting of faces on the workpiece (that is, surfaces perpendicular to its rotating axis), whether with a turning or boring tool, is called "facing", and may be lumped into either category as a subset.Turning can be done manually, in a traditional form of lathe, which frequently requires continuous supervision by the operator, or by using an automated lathe which does not. Today the most common type of such automation is computer numerical control, better known as CNC. (CNC is also commonly used with many other types of machining besides turning.)
Steel liner, Cast iron piston
This combination gives the highest possibility of producing a runable and durable engine that will have expected working life under predicted quality. Enginners prefer this combination for small and medium size engines. Very important part when using this combination is that the bore should be pointed, wider below the exhaust ports.
Cast Iron liner, Cast Iron piston
This is a little bit difficultier operation then the last one because of the brittle nature of thin walled cast iron turnings. The liner requires care and a bit of prior experince in workholding. In this process, the cylinder is roughed out, then the bore is finished, but not honed. It is next packed with case hardening compound using a bolt and two large washers to cover the ends. It is not "case hardened" as such, and is significantly softer, but the results are worthwhile. This combination doesn’t give any specific advantage in regard to previous combination.
Steel liner, Steel piston
Both components must be hardened, with piston tempered to 10 Rockwell c points lower than liner to minimize gailing. Higher oil usage is preffered for this combination. Tolerances are very small.
Steel liner, Aluminium piston with Cast Iron ring(s)
This combination has a highest priority. Requires experencied workers for making this combination possible for combination in engine. Errors are not allowed. Ringed piston doesn’t need honing.
best suited for larger engines. If its created with precision and care, the combination will produce an excellent, long lasting engine
When developing
the designer has more choices for element cylinder/piston, but everything has
its advantages and disadvantages.Some of the features are:
Steel liner, Cast Iron piston
Cast Iron liner, Cast Iron piston
Steel liner, piston Steel
Steel liner, piston Aluminium, Cast Iron ring (s)
As alone two elements
are interrelated function play a very important role and it is therefore very
important to maintain an optimal working relationship between these two
elements, because such operating parameters are very important.Steel liner, Cast Iron piston
Cast Iron liner, Cast Iron piston
Steel liner, piston Steel
Steel liner, piston Aluminium, Cast Iron ring (s)
There are other possibilities, but these above are actually the nearest optimal and most cost.
Machining processes that help in this are honing and turning.
Honing is an abrasive machining process that produces a precision surface on a metal workpiece by scrubbing an abrasive stone against it along a controlled path. Honing is primarily used to improve the geometric form of a surface, but may also improve the surface texture.
Turning is a machining process in which a cutting tool, typically a non-rotary tool bit, describes a helical toolpath by moving more or less linearly while the workpiece rotates. The tool's axes of movement may be literally a straight line, or they may be along some set of curves or angles, but they are essentially linear (in the nonmathematical sense). Usually the term "turning" is reserved for the generation of external surfaces by this cutting action, whereas this same essential cutting action when applied to internal surfaces (that is, holes, of one kind or another) is called "boring". Thus the phrase "turning and boring" categorizes the larger family of (essentially similar) processes. The cutting of faces on the workpiece (that is, surfaces perpendicular to its rotating axis), whether with a turning or boring tool, is called "facing", and may be lumped into either category as a subset.Turning can be done manually, in a traditional form of lathe, which frequently requires continuous supervision by the operator, or by using an automated lathe which does not. Today the most common type of such automation is computer numerical control, better known as CNC. (CNC is also commonly used with many other types of machining besides turning.)
Steel liner, Cast iron piston
This combination gives the highest possibility of producing a runable and durable engine that will have expected working life under predicted quality. Enginners prefer this combination for small and medium size engines. Very important part when using this combination is that the bore should be pointed, wider below the exhaust ports.
Cast Iron liner, Cast Iron piston
This is a little bit difficultier operation then the last one because of the brittle nature of thin walled cast iron turnings. The liner requires care and a bit of prior experince in workholding. In this process, the cylinder is roughed out, then the bore is finished, but not honed. It is next packed with case hardening compound using a bolt and two large washers to cover the ends. It is not "case hardened" as such, and is significantly softer, but the results are worthwhile. This combination doesn’t give any specific advantage in regard to previous combination.
Steel liner, Steel piston
Both components must be hardened, with piston tempered to 10 Rockwell c points lower than liner to minimize gailing. Higher oil usage is preffered for this combination. Tolerances are very small.
Steel liner, Aluminium piston with Cast Iron ring(s)
This combination has a highest priority. Requires experencied workers for making this combination possible for combination in engine. Errors are not allowed. Ringed piston doesn’t need honing.
best suited for larger engines. If its created with precision and care, the combination will produce an excellent, long lasting engine
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