Tubular is a word that we come across very often in our daily lives. It is used to describe cylindrical objects or structures that resemble tubes. This term finds its usage in a wide range of fields- from science to surfing! Read on to know more about what tubular means and its applications in different areas.
The Meaning of Tubular
Tubular is an adjective that describes objects or structures that are in the shape of a tube. The term can be traced back to the Latin word ‘tubulus’, which means a little pipe. In modern times, the word is used to describe various cylindrical objects and structures that have a hollow center.
Tubular in Surfing
One of the most common uses of the word ‘tubular’ is in surfing. In this context, it is used to describe the perfect wave that has a cylindrical shape. Surfers use the term ‘tubular’ to indicate that they have ridden a wave that has formed a hollow tube. It is highly desirable to surfers because it allows them to ride within the wave and experience a unique rush of adrenaline.
Tubular in Science
In science, the concept of ‘tubular’ is quite broad. It is used to describe various cylindrical structures. For instance, the human body contains many tubular structures, such as the esophagus, bronchi, and urethra. Similarly, in botany, the term is used to describe roots, stems, and leaves that have a cylindrical shape.
The Applications of Tubular
Tubular objects and structures have various applications in different fields. Below are some of the areas where the concept of tubular finds its usage:
Engineering
The concept of tubular is used extensively in engineering. Tubular structures are designed to withstand high loads and provide efficient load transfer across the length of the structure. Therefore, tubular structures find their applications in construction, aerospace, and marine engineering, among others.
Medical Science
The medical field widely uses tubular structures, such as catheters and stents, to diagnose and treat diseases. These instruments are designed to reach the internal organs through tubular structures present in the body, such as veins, arteries, and the gastrointestinal tract. Similarly, in dentistry, root canals are performed on tubular structures present in teeth.
Manufacturing
Tubular structures are extensively used in the manufacturing industry. They are used to create products and structures with cylindrical shapes, such as pipes and tubes, cylinders, and storage tanks. These structures are used in a wide range of applications such as oil and gas transportation, water supply systems, and industrial processes.
The Advantages of Tubular Structures
Tubular structures are unique in their design and have numerous benefits over other traditional forms. Some of their essential advantages are:
Strength and Durability
Tubular designs provide excellent strength and durability. They distribute stress uniformly across their length, minimizing the chances of failure. Therefore, tubular structures are widely used to build tall buildings, bridges, and other large engineering projects.
Less Material Required
Tubular designs require less material than other traditional designs. They provide the same strength and rigidity with less material, making them an economical choice for manufacturers and builders.
Flexibility in Design
Tubular structures offer a wide range of design options. The cylindrical shape allows designers to create unique and aesthetically pleasing structures. They can use different diameters, cross-sections, and wall thicknesses to create structures that fit specific requirements.
The Future of Tubular Structures
Tubular designs have been around for centuries, and their applications are continually evolving. With advances in technology, the future of tubular structures is bound to be exciting. The design possibilities are endless, and new applications in fields such as nanotechnology and robotics are continuously being discovered. The future of tubular structures is bright.
Conclusion
Tubular structures are ubiquitous in our daily lives. They are used extensively in various fields, from engineering to medicine. Their unique cylindrical design provides numerous advantages in terms of strength, durability, and flexibility. The future of tubular structures looks bright, and their applications are bound to grow with advancements in technology.
Common Questions and Answers
- What is a tubular structure?
- What is a tubular wave?
- What are some of the applications of tubular structures?
- What are the advantages of tubular structures?
- What is the future of tubular structures?
A tubular structure is an object or structure that is in the shape of a tube. The term is used to describe various cylindrical objects and structures that have a hollow center.
A tubular wave is a wave that has a cylindrical shape. Surfers use the term ‘tubular’ to indicate that they have ridden a wave that has formed a hollow tube.
Tubular structures have various applications in different fields, including engineering, medicine, and manufacturing.
Tubular designs provide excellent strength and durability, require less material, and offer a wide range of design options. They are also an economical choice for manufacturers and builders.
With advances in technology, the future of tubular structures is bound to be exciting. The design possibilities are endless, and new applications in fields such as nanotechnology and robotics are continually being discovered.
References
- N. Sankarankutty, J. J. Xin, C. Kassapoglou, M. R. Wisnom, and R. C. Alderliesten. “Design Optimization of Tubular Structures Subjected to Combined Compression and Bending Using a Genetic Algorithm.” Computers & Structures, vol. 114-115, pp. 191-204, 2013.
- S. Singh, S. Bhattacharya, and S. Dasgupta. “Numerical Analysis of a Composite Tubular Joint Under Axial Compression and Oblique Loading.” Journal of Reinforced Plastics and Composites, vol. 36, no. 21, pp. 1550-1561, 2017.
- A. Bondarenko, V. Dubrovskyi, and R. Kuznietsov. “Theoretical Analysis of Stress Concentrations in Tube-to-Tube Sheet Joints.” Journal of Pressure Vessel Technology, vol. 140, no. 2, pp. 1-9, 2018.