History Of Brakes And Principles Of Hydraulics Engineering Essay

History Of Brakes And Principles Of Hydraulics Engineering EssayLanding slopes ar one of the most important parts of the aircraft and play an important use because it can make the aircraft run through runways and lands the aircraft to safety with the aid of the braking carcass and other systems. The modern brake system has been refined for all over 100 eld and has become extremely dependable and efficient. The whole draft talks about the hydraulic brake system. Modern braking systems are complicated and understanding the subprogram of a braking system requires specialized skills and training. Brakes are the most important have of any modern transportation these days.The principles of brakes in a landing gear of the aircraft gave us the idea that making a simple hydraulic break system would be our main project. The content is designed to show the insight of the principles of operation of the hydraulic break, components and its functions. The advantages and disadvantages agains t different types of brakes and other terminology.History oF BrakesAll cars need a brake system therefore it has been present in the political machine since its introduction. However, the technology of the components and the design of the brake system have evolved throughout the years.In the early days of the automobile, organize brakes were the standard. Drum brakes offered several advantages over other types of brakes. One of these was that the drum could keep out water and dust, materials that could damage dish aerial brakes which were out in the open. The other, more important advantage was that drum brakes required drivers to grant less impel on the pedal as compared to disc brakes. This was especially important in the days before hydraulic and power brake systems, both of which decreased the amount of pedal pressure needed.The next major advancement in brake technology came in 1918 with the invention of four-wheel hydraulic brake systems by Malcolm Loughead. It is intere sting to note that Loughead was a member of the Lockheed family, a company known better for producing airplanes. The hydraulic brake system re lay the mechanistic brake system that was in use at this time. The mechanical system had numerous disadvantages. It made it difficult to brake all the wheels evenly, often do a loss of control. In addition, it required drivers to exert tremendous amounts of force on the brake pedal to slow the car. The hydraulic brake system reckon the force that was applied to the brake, lessening the amount of force needed to be applied to the brake pedal by the driver. This system was first apply in the 1918 Duesenberg. Its advantages quickly caught on and by 1929, four wheel hydraulic braking systems were standard equipment on most higher priced cars. It took a few more years for the feature to become familiar on lower price cars.As the speed of automobiles and their weight increased, better braking systems were required. The main problem with drum b rakes is that the lovingness is not efficiently disbursed. The heat that is produced inside the drum does not escape easily since the drum prevents wind from drawing it away. However, disc brakes were open to the passing wind. This allowed the heat to be carried away which increased the efficiency of the brake. It is interesting to note that disc brakes were first used in 1902. However, their use was limited up until the fifties since their efficiency was not required and they required more pedal pressure to operate. The reason for the higher pedal pressure is that disc brakes have no self-servo effect or no self-energizing capacity that the drum brakes have. The self-servo effect is caused by the forward motion of the car. This forward motion helps pull the brake skid into contact with the drum. This helped lower the required pedal pressure. Now that their efficiency was needed and the hydraulic brake system multiplied the force applied to the brake pedal, disc brakes seemed to be the better alternative. Chrysler was the first to widely introduce the disc brake in its cars in the early 1950s. The system did not have overmuch success. It seemed that the brake pressure required of the driver was still a little to great for the system to gain widespread consumer acceptance and therefore it was dropped. It finally took the weakness automaker Studebaker to reintroduce the system in 1964. This time it saw much more success and in a few years, disc brakes were putting green on most new cars.One of the reasons that disc brakes were a success with the Studebaker and not the Chrysler was due to the development of the power braking system. Power brakes became common in the 1950s, after Chrysler had developed and dropped its disc brake program. The system assisted the movement of the piston in the master cylinder which meant that the driver needed to apply less peddle pressure to get the same braking effectiveness. Therefore, since ease of braking was no longer an issue, the adoption of the more efficient disc brake became widespread.Another development in braking systems came with anti-lock or anti-skid braking. With conventional braking systems, when the brakes are applied with enough pressure, the wheels will lock up. This results in a loss of steering effectiveness which whitethorn cause a loss of control. With anti-lock braking, the wheels do not lock up, allowing the driver to continue steering. Anti-lock brakes are not a new technology. They had been used in big(p) aircraft since the 1950s and the British had used them in race cars in the 1960s. The first automaker to use this technology in its cars was Ford in 1969. It placed anti-lock brakes in the luxury Thunderbird and Continental Mark III. Today, anti-lock brakes are common on many new cars. Basic Principles of HydraulicsWhat is pressure? drive can be defined as the force per unit area and is expressed in Newtons per square millimeter (N/mm) or in debar and pounds per square in ch (lbs/in) or p.s.i. in U.S. pressure.Formula P = F / A Where P = Pressure F = Force A = theatreWhat is hydraulics?Liquids or quiets which are under pressure are usually used to transmit power through pipelines. The changeful power is converted into mechanical power by using rotary or linear actuators.What is Pascals Law?Pascals Law comprises a set of principles formulated in 1648 and states that pressure applied to a confined fluid at any point is transmitted undiminished throughout the fluid in all directions and acts upon every part f the unaired vessel at right angles to its interior surfaces and equally upon equal areas.It defines the fundamental principle of power transmission by a hydraulic system. gauge 2 Pascals LawPressure is created only whenThe system is closedThere is no air trapped in the systemAn attempt is made to compress the fluidAnother important relationship in hydraulics is the area of the piston, the distance it moves, and the volume of fluid displaced.For mula Volume =Area * DistanceFluid sponginessAll liquids have a very high guard to compression while air has a very low resistance to compression. Liquids used in hydraulic systems are also known as hydraulic fluids.Figure 3 Hydraulic fluidBramahs PressStates that under a given load, the littler the area it acts upon the greater the pressure produced and the greater the area under pressure, the greater the force available.Pressure = Load / AreaFigure 4 Bramahs PressIn an aircraft hydraulic system, Bramahs principle can be applied to the movement of different loads using actuators subject to one pressure. The figure above shows a large load and a small load being pushed by actuators having different piston areas.Bernoullis Principle The relationship between the velocity and pressure exerted by a moving liquid is described by the Bernoullis principle as the velocity of a fluid increases, the pressure exerted by that fluid decreases and as fluid decreases, pressure is increased.Figure 5 Bernoullis PrincipleFigure 6 Bernoullis principle also allows wings to produce liftHydraulic FluidsHydraulic system fluid or liquids are used to transmit and to distribute the fluid to various units to be actuated. They are able to do this because they are almost compressible. If a number of passages make it in a system, pressure can be distributed to all of system by means of the liquid.Manufacturers of hydraulic devices usually specify the type of liquid beaver suited for use with their equipment, during working conditions, the service required, temperatures expected inside and outside the systems, pressures the liquid may withstand, the possibilities of corrosion, and other conditions.Figure 7 Types of hydraulic fluid Figure 8 Hydraulic Fluid (Aeroshell brand)Properties of FluidFluids are incompressibleThey have a reasonable density with very little variation changes in temperature. petty(a) rate of change of viscosity with temperature changesLarge working range of temperatu re (-80C to +70C)Good Lubricating PropertiesIt isnt harmful when in in contact (skin, hands)It doesnt foamchemically stable with changes in temperatureGood storage lifeDoesnt attack nor damage rubber.Fluid is preferably non-flammableEfficiencyFriction between the fluid and the walls of the pipes depends uponThe velocity of the fluid of the pipelinesThe bore, length and internal finish of the pipelinesThe number of bends in the pipelines and the radii of the bendsThe viscosity of the fluidWhat is Viscosity?It is one of the properties of hydraulic fluid.Viscosity is internal resistance to flow.Viscosity increases with a decrease in temperature.The knowledge of viscosity is needed for proper design of required temperatures for storage, pumping or injection of fluids.There are twain related measures of fluid viscosity known as dynamic (or absolute) and kinematic viscosity.Types of Hydraulic Fluid1 Vegetable Based (MIL-H-7644) is composed of a caster petroleum and alcohol. It is dyed blue. They are mostly used in older type aircraft. Natural rubber seal are used with vegetable base hydraulic fluid. This type is flammable. And the system may be cleaned with the use of alcohol.Figure 9 Vegetable based fluid2 Mineral Base (MIL-H-5606) it is processed from petroleum. It has an perfume similar to penetrating oil and is dyed red. Synthetic rubber seals are used with petroleum base fluids. This type of fluid is flammable. They are used in common aircrafts and the precaution is damaging to rubber tyres.Figure 10 Mineral base fluid3 Synthetic Base (MIL-H-8446) This is one of the most ordinarily used fluid of this type. This fluid is of a clear purple colour or either dyed green. They are fire resistant. The seal material used is synthetic butyl Teflon and the precaution is of damaging to surface finishes.Figure 11 Synthetic base fluidThese three types of fluids cannot be mixed nor any of them are compatible with each other.