What Are The Fields Where The Mechanical Engineers Work As Consulting Engineers?

Mechanical engineers have the liberty to work in different fields, and even serve the purpose of the consulting engineers when their clients seek their guidance. In this blog, we have covered the industries.

where mechanical engineers are widely known to work.

 

 

 

1. Aerospace

The aerospace engineers focus on flights, which include planes, rockets, and missiles. They are known for designing greater fuel-efficient and functionality-oriented aircraft which cut dimensions, build up the satellite fleet for powering modern-day GPS technology and create spacecraft for the next generations to aid in scientific studies and researches in space. 

2. Constructions and Buildings

Mechanical engineers are relied upon for the success of major construction projects since they have the knowledge for focussing on the details. It means they have to play the role of the consulting engineers for various projects in Brisbane and design the heating, cooling, and ventilation systems for skyscrapers. They even have to choose the ideal way for delivering the mains gas to the entire housing estate, and ensure the new metro tunnel project has incorporated the necessary services for making maximum utilization and advantage of the undercity space.

3. Automotive

Mechanical engineers are even known to drive the automobile industry. Starting with the 80 or more seater busses to the single-seat F1 cars, the mechanical engineers can design the wheelsets, bodyshells, and combustion systems for all types of moving vehicles. Even all the traditional fuels are not concerned - the automobile mechanical engineers are also working on the solar panels as well as hydrogen cells along with other technologies for finding out better ways and solutions for keeping the people moving.

4. Biomedical

Mechanical engineers help in changing lives by working in the biomedical industry. They have the ability in creating better and more lifelike artificial limbs for helping the injured and disabled to improve the quality of their lives. The robotics surgical assistants, pacemakers, and artificial valve assistants are the works done by the mechanical engineers, and even the running blades the athletes use at Paralympic events.

5. Manufacturing

Mechanical engineers are responsible for making the manufacturing finally be successful. It could be the high volume goods, specialist ultra-tech equipment, mass-produced goods- the mechanical engineers have the ability in creating the machines and technology for designing and producing the goods on which the population heavily relies on.

6. Power

Mechanical engineers work to power the world. They can generate and deliver the needed energy. It could include designing the nuclear plans and biomass boilers, plan on new long-distance grid connections, storing power sustainably in the solar storage cells, and giant hydroelectric batteries which are buried under the mountains.

7. Process

The mechanical process engineers specialize in bringing about improvements in the way we are doing things. First, they make an assessment of the mechanical processes, then find out ways for making them a lot more efficient and safe, and deliver standard and better quality. It indicates they are directly affecting the major mechanical industries, starting from the water supply, oil and gas supply, and through food manufacturing and pharmaceuticals.

8. Railways

Almost each and every aspect of the railways are dependent on mechanical engineering. Starting from tracks, trains and signals, to the tunnels and ticket barriers, the mechanical engineers take responsibility for the elaborate control systems. The new solutions are necessary for dealing with record passenger numbers, building up a thousand miles of high-speed railway, and developing faster propulsion methods.

The mechanical engineers, as pointed out in our discussion have to work in diverse industries, and implement their skills and expertise for ensuring the ultimate products are safe for being used and are long-lasting. Only the mechanical engineers and settle on the exact materials needed for a specific project, and likewise play the role of consulting engineers to guide the workers and clients.

Different Types Of Structural Steel Shapes

Structural steel is the most versatile and flexible materials in the world. This steel is used in several construction projects such as bridges, skyscrapers, marine piers etc. It is available in different sizes and shapes. According to the shapes, structural steel is classified into different categories. 

 

 

They include S beam, L beam, bearing pile or H beam, C beam, hollow section, I beam etc.

1. S Beam

S-shaped beam is also known as American standard beam. This beam has 2 parallel flanges with the rolled section. They are generally connected to each other by a web. The web can resist the shear forces The flanges of this beam are narrow. It has a very high strength and widely used for many Structural Engineers projects in Brisbane.

2. L-Beam

L shape is also called the angled beam. It has 2 legs that create a 90-degree angle. The leg size may be equal. For example, the leg sizes of an unequal angle beam are 2x2x0.5 and 6x3x0.5 units. This beam is mostly used in building foundations. L beam always offers huge stability to the floor systems while minimising the structural depth.

3. Bearing Pile 

Structural engineers or experts in Brisbane generally use bearing piles for building a deep foundation. This pile is also known as H shape beam. It has very high strength and easily bears more than 1000 tons. H beam looks like an I beam. However, H beam is relatively heavier as compared to I shaped beams. The flanges and webs of this beam have an equal thickness in different cases.

4. C-Beam  

Structural C beam has different names: C channel, structural channel, C shaped cross-section etc. This beam generally consists of a top flange, a bottom flange. They are connected with the web. This beam is very less expensive as compared to other structural beams. It is generally used in bridges, marine piers and other building structures.

5. Hollow Section 

Hollow sections or HSS are the steel profiles. They are available in several sizes and shapes. Some common shapes of the HSS beams are rectangular, square, circular, elliptical, etc. Engineers mainly use these sections in several welded metal frames. They have very high strength.

6. I-Beam 

I-beam is also known as H beam or universal beam. This beam has 2 horizontal elements. This beam can effectively bear bending and shear loads. It comes with different sizes. The web of this beam can resist the shear force and the flanges can resist the bending movement. I beam is generally used as the main framework and support trusses.

So, these are the different types of structural steel shapes. They have extremely high load-bearing strength. They have a wide range of applications. In Brisbane, these structural steel shapes are used in different constructional projects.

Why Run Finite Element Analysis Services In Solid Works?

Finite Element Analysis or in short FEA denotes the simulation technique the software packages have employed for the engineers to simulate the assemblies and parts will be responding under various loading conditions. Through the Solid Works Simulation packages, the engineers can carry our models' interrogation quickly and easily so that the managers and owners can make informed design decisions, and finally serve as a guide in the manufacturing process.

 

 

Hence for every construction purpose, incorporating the Finite Element Analysis services in Brisbane into the design process as instructed by the engineers from reputed engineering firms, since there are several reasons for doing so - 

1.The simulation clearly works with all the non-invasive files, and even it fits perfectly right into Solid Works.

You might work with the imported files from other sources or the vendors - Solid Works Simulation does the task in a similar way. The native Solid Works files are not needed for running the analysis on geometry.

2.The physical prototypes are both time-consuming and expensive.

The reason for the traditional iterative design process to be bottle necked is the fast manufacturing process of the prototypes, and producing them is extremely expensive. Through Solid Works Simulation, this particular bottleneck can be eliminated by getting the prototyping virtually done and by reducing the number of produced physical prototypes. 

3.The computer will be doing all the work.

The key advantage of Finite Element Analysis is leveraging the power of computers and making them churn out results, while you are focusing on the other aspects. As soon as the study begins, the software starts to take over and provides the engineer with the desired results automatically once the study is done. Smart work is better than hard works.

4.What about establishing direct access to CAD?

Exploring the potential changes in the assembly file or the part becomes easier when there is secured direct access to the CAD geometry. Other than waiting for another physical prototype for being fabricated, changing the dimensions takes only a few minutes. It will be possible to re-run the study for exploring the effects. Having the opportunity for making the changes or shift to both the geometry as well as the loading conditions of the simulations facilitates in numerable possibilities prior to the first physical part being produced. 

5.The engineering firm could already be the owner of the Simulation.

Solid Works Simulation Standards are available with the licenses of the Solid Works Premium, thus, the engineers are likely to already have access to the Simulation.

Finite Element Analysis services are involved in piping and pressure vessel fields, and this simulation technique is run to the Solid Works software package for the benefit of the engineers and construction designs. The discussion has pointed out the reasons why the engineers work by integrating the technique for the sake of smart and faster work.