Emerging from the Bongo

STAR WARS EPISODE I: The Phantom Menace 00:21:29

my toxic trait is i hate pluto as a planet discourse not because i think pluto is a planet but because i fucking loath the iau's definition of a planet.

it relies on ambiguous concepts with no agreed setpoint, both "clearing the neighbourhood" and "hydrostatic equilibrium", arbitrarily excludes objects outside a solar system from planethood*, gets extremely weird with things like brown dwarfs, and in general basically assumes our solar system as the default to base things off of and thus gets messed up with anything that doesn't occur in our system

i hate it and i hate that everyone swings so far into "support science" that they end up dismissing the actual debates happening within a field.

*technically rogue planets aren't planets, even if they meet all other criteria and started as planets before being ejected from its system. because planets are defined by being in a solar system.

Why Titanium Tubes Are the Backbone of Modern Engineering: Strength, Performance, and Precision

In industries where strength, reliability, and precision are non-negotiable, Titanium Tubes have earned their place as a superior choice over conventional materials. From aerospace engines to offshore drilling rigs and medical implants, titanium tubing plays a pivotal role in some of the most demanding applications in the world.

So, what makes Titanium Tube so valuable across such a wide range of sectors? Let’s dive into the core characteristics, applications, advantages, and selection criteria of this remarkable material.

What Is a Titanium Tube?

A Titanium Tube is a cylindrical hollow product made from various grades of titanium—typically Grade 2 (commercially pure) or Grade 5 (Ti-6Al-4V), an alloy with aluminum and vanadium. It can be seamless or welded, and it’s known for its strength-to-weight ratio, corrosion resistance, and ability to perform in extreme environments.

Titanium tubes are available in various diameters, wall thicknesses, and lengths, making them versatile for custom specifications and tight engineering tolerances.

Core Properties That Make Titanium Tubes Stand Out

1. High Strength-to-Weight Ratio

Titanium is as strong as steel but around 45% lighter, which is why it’s ideal for aerospace, automotive, and sporting applications.

2. Exceptional Corrosion Resistance

Titanium naturally forms a protective oxide layer that resists corrosion from seawater, chlorine, and even acidic environments—outperforming stainless steel and aluminum.

3. Excellent Temperature Stability

Titanium tubes can maintain mechanical properties at high temperatures (up to 600°C) and also perform well in cryogenic conditions.

4. Biocompatibility

Titanium is non-toxic and compatible with human tissue, making it perfect for medical implants and surgical instruments.

Titanium Tube Applications by Industry

Aerospace & Defense

Titanium tubes are used in:

Aircraft hydraulic systems

Fuel and oil transport lines

Exhaust and heat exchange systems

Their lightweight yet durable profile helps increase fuel efficiency and structural integrity.

Marine & Offshore

Used in seawater systems, riser pipes, and underwater robotics, titanium tube resist corrosion even in harsh saltwater environments.

Medical Field

Titanium is a go-to material for:

Orthopedic implants (bone screws, hip replacements)

Surgical instruments

Dental tools

Chemical & Petrochemical

Titanium tubes withstand corrosive chemicals and high pressures in:

Heat exchangers

Condensers

Process pipelines

Energy & Power Generation

Titanium tubes are used in nuclear plants, geothermal applications, and desalination systems due to their longevity and thermal stability.

Seamless vs Welded Titanium Tubes: What’s the Difference?

Welded Rolled and welded from titanium sheets—more cost-effective      Architectural, industrial, and moderate-pressure applications

Titanium Tube suppliers typically offer both types, depending on your application and budget.

Each grade has its own strengths depending on the application, and a reliable Titanium Tube supplier will guide you to the best match.

How to Choose the Right Titanium Tube Supplier

When sourcing Titanium Tubes, quality and compliance are crucial. Consider the following:

Certifications: Look for ASTM B338, B861, or ISO certifications.

Traceability: Ensure full traceability of material origin and production.

Customization: Does the supplier offer cut-to-length services or specialty finishes?

Experience: Work with suppliers experienced in your industry.

Testing: NDT (non-destructive testing), hydrostatic, and ultrasonic tests ensure tube integrity.

Is Titanium Sustainable?

Yes. Titanium is not only long-lasting but also 100% recyclable. Although its extraction and processing are energy-intensive, the long-term benefits of corrosion resistance, lower maintenance, and extended lifespan make it a sustainable material—especially for industries looking to reduce their carbon footprint.

Future Trends: Titanium Tubes in Green Technology

As industries aim for lighter, stronger, and cleaner solutions, titanium tubes are increasingly being used in:

Hydrogen fuel systems

Electric vehicles (EVs)

Renewable energy infrastructure (wind, solar, hydro)

Space exploration technologies

These trends suggest long-term growth in demand for high-quality titanium tubing.

Conclusion: Invest in Strength, Reliability, and Innovation

Titanium tubes may cost more upfront than traditional metals, but their longevity, strength, and corrosion resistance often result in lower lifecycle costs and enhanced performance. Whether you're in aerospace, marine, chemical processing, or healthcare, Titanium Tubes are a smart and future-ready investment.

Ready to get started? Choose a supplier that understands the nuances of titanium production and your industry's needs. With the right Titanium Tube, you're building not just a product—but lasting performance and safety.

Structural characteristics and heat dissipation methods of CNC spindle motors

1.Working principle of CNC spindle motors CNC spindle motors usually use AC motors, and their working principle is based on electromagnetic induction. There are stators and rotors inside the motor, and AC coils are wound around the stators. When power is turned on, a rotating magnetic field is generated. The conductor in the rotor will generate eddy currents under the action of the rotating magnetic field, and then generate electromagnetic force to drive the rotor to rotate. By controlling the input AC frequency, the speed of the motor can be changed to achieve the speed regulation function.

2.Heat dissipation methods of CNC spindle motors

1.Water cooling: Water cooling is to cool the heat generated by the high-speed rotation of the spindle through water circulation. The core components of the water cooling system include the coolant inlet and outlet. The coolant circulates in the system, takes away the heat generated by the spindle, and is discharged through the coolant outlet. The advantages of water cooling include good heat dissipation, low noise, long service life, and high precision. However, it should be noted that in cold areas, the circulating water may freeze and damage the spindle.

2.Air cooling: Air cooling is to dissipate heat through a fan. The air-cooled spindle relies on its own fan for cooling. Although the heat dissipation effect is not as good as water cooling, it has a simple structure and low cost. The air-cooled spindle may damage its service life when working continuously for a long time, and usually needs to rest regularly to avoid overheating.

3.Structural characteristics of CNC spindle motors ‌1. Integrated design: CNC spindle motors usually adopt an integrated design, that is, the rotor of the motor is directly used as the spindle of the machine tool, and the housing of the spindle unit is the base of the motor. This design makes the spindle and the motor closely integrated, reduces the length of the transmission chain, and improves mechanical efficiency and precision. ‌2. Bearing type: Common bearing types for CNC spindle motors include ceramic ball bearings, hydrostatic bearings and magnetic bearings. Ceramic ball bearings are lightweight and high hardness, which can effectively reduce the centrifugal force and internal load of the bearing, reduce wear and extend service life; hydrostatic bearings are widely used due to their advantages of low wear, long life and low vibration; magnetic bearings achieve high precision and high speed performance through non-contact suspension design, but the cost is relatively high. ‌3. Cooling system‌: Since high-speed operation will generate a lot of heat, CNC spindle motors are usually equipped with cooling devices, such as forced circulation oil cooling systems, which remove heat through circulating cooling oil to keep the temperature of the spindle unit within an appropriate range. ‌4. Drive mode‌: CNC spindle motors mostly use AC asynchronous induction motors, which are widely used because of their reasonable price, high limit speed, and convenient maintenance. The drive mode includes inverter drive and vector control drive drive. The former is a constant torque drive, and the latter is a constant torque drive at the low speed end and a constant power drive at the medium and high speed ends.

4.Common application areas of CNC spindle motors ‌1. Oil and gas exploration‌: In oil and gas exploration, CNC spindle motors can go deep into the ground for thousands of meters to find oil and gas resources. Deep hole drilling rigs use CNC spindle motors for high-precision drilling operations to meet the needs of oil and gas exploration. ‌2. Aerospace‌: In the field of aerospace, CNC spindle motors are used to manufacture high-precision parts such as aircraft engines and rocket components. It can process complex hole shapes, meet the requirements of lightweight and high strength, and is widely used in the manufacture of aircraft engines and fuselage parts. ‌3. Automobile manufacturing: In automobile manufacturing, CNC spindle motors are used to process key components such as automobile steering systems and brake systems. Its high precision and high efficiency make the processing of automobile parts more precise, improving the performance and reliability of the car. ‌4. Mold manufacturing: In mold manufacturing, CNC spindle motors are used to process mold cooling holes and injection holes to improve the service life of the mold and product quality. Its precise control and high efficiency make the processing of molds more efficient and accurate. ‌5. CNC lathe: CNC lathe is one of the important application areas of CNC spindle motors. CNC lathes use components such as computers, CNC devices and servo systems to accurately control the machine tools according to pre-set programs to process various complex parts. CNC lathes are widely used in many fields such as machinery manufacturing, automobile manufacturing, aviation manufacturing, medical equipment and electronic products. ‌4. High-speed machining‌: In the field of high-speed machining, CNC spindle motors can achieve high-speed and high-precision machining. Its direct transmission structure eliminates the intermediate transmission link, improves machining efficiency and precision, and is widely used in high-speed CNC milling, high-speed engraving and milling, machining centers and other fields‌.

Premium A519/SA519 Chrome Moly Tubes in Japan by Hanko Steel

High-performance materials are essential for guaranteeing effectiveness, safety, and durability in the dynamic fields of industrial manufacturing and engineering. The A519/SA519 Chrome Moly Tube is one such crucial product that is utilized extensively in petrochemical, oil and gas, power generation, and automotive industries. Hanko Steel is a well-known Manufacturer of A519/SA519 Chrome Moly Tubes in Japan that meet both domestic and international requirements with consistent quality and performance in Japan, where the market is dominated by precision engineering and high standards.

What are A519/SA519 Chrome Moly Tubes?

Chromium-molybdenum alloy steel is used to make seamless mechanical tubing known as A519/SA519 tubes. These tubes are designed especially for uses that call for strength, durability to high temperatures, and superior corrosion resistance. Chromium (Cr) and molybdenum (Mo) improve the mechanical characteristics of the tube, which makes it perfect for settings with high temperatures and pressures. These tubes meet the widely used ASTM A519 and ASME SA519 requirements in international markets. Boiler tubes, heat exchangers, superheater tubes, and parts for automobile transmissions are typical uses. They are an essential part of important systems because of their capacity to endure severe stress conditions without deforming.

Hanko Steel: Delivering Quality and Reliability in Japan

Product Range and Specifications

Hanko Steel is one of the Finest Manufacturer of A519/SA519 Chrome Moly Tubes in Japan A519/SA519 Chrome Moly Tubes from Hanko Steel are available in a wide variety of grades, including AISI 4130, 4140, and 4145. Depending on the needs of the customer, the tubes come in a variety of lengths, wall thicknesses, and outer diameters. Hanko Steel guarantees precise surface finishes and tight dimensional tolerances for both conventional sizes and custom solutions. The company's state-of-the-art testing and manufacturing facilities follow strict quality control procedures, such as non-destructive assessments, hydrostatic testing, and ultrasonic testing. Complete documentation and traceability, including mill test certificates and third-party inspection reports if necessary, are included with every tube that is supplied.

Commitment to the Japanese Market

Hanko Steel has established a robust supply chain and customer service presence throughout the region because of its understanding of the particular requirements of the Japanese industrial sector. For its Japanese clients, the company prioritizes timely delivery, reliable inventory, and technical assistance to guarantee seamless project execution and procurement. In keeping with Japan's strong emphasis on sustainability and eco-efficiency, Hanko Steel prioritizes ecologically friendly methods in addition to offering cheap pricing. They are a recognized provider of Chrome Moly tubes in Japan because of their commitment to industry-compliant solutions, precision engineering, and customer satisfaction.

Conclusion

A519/SA519 Chrome Moly Tubes and other dependable, high-performance materials are becoming more and more in demand as Japanese industries continue to push the limits of efficiency and innovation. With its superior product quality, customer-focused strategy, and technical know-how, Hanko Steel is well-positioned to satisfy this expanding demand. In Japan's cutthroat industrial environment, Hanko Steel maintains its position as a top provider of Chrome Moly Tubes by providing reliable value and performance. For More Details CLICK HERE

Control and maintenance methods of CNC spindle motors

1.Introduction to CNC spindle motors CNC spindle motors, also known as electric spindles, refer to a new technology that integrates the machine tool spindle and spindle motor in the field of CNC machine tools. This design shortens the length of the machine tool main drive chain to zero, achieving "zero transmission", that is, the motor directly drives the spindle, thereby improving mechanical efficiency and precision.

2.Control methods of CNC spindle motors 1.Variable frequency speed control: This is one of the most common control methods for CNC spindle motors. By controlling the speed of the motor through the frequency converter, the spindle can be controlled steplessly. Variable frequency speed control can be divided into ordinary variable frequency drive, vector control and direct torque control. ‌ 2.Analog spindle control: FANUC CNC system uses analog voltage to control the spindle, and outputs 0~+/-10V analog voltage to control the start, stop, forward and reverse rotation and speed regulation of the spindle. The programming processing instruction is M03/M04Sxx. ‌3.Serial spindle control‌: In the FANUC 0i series CNC system, data control and information feedback are carried out between the CNC controller and the spindle servo amplifier through serial communication. Serial spindle control requires physical electrical hardware connection and spindle function configuration‌.

3.Structure of CNC spindle motor ‌1.Housingless motor‌: CNC spindle motors usually adopt a housingless motor design. This design allows the stator part of the motor to be placed in the housing of the spindle unit, and the rotating parts of the rotor and spindle are integrated, thereby achieving a compact structure and high-efficiency operation of the motor‌. ‌2.Bearing‌: Bearings are an important component of CNC spindle motors and mainly bear radial and axial forces. Common bearing types include ceramic ball bearings, hydrostatic bearings, and magnetic bearings. Ceramic ball bearings are lightweight and high-hardness, suitable for high-precision machining; hydrostatic bearings reduce wear and improve rotation accuracy by non-direct contact; magnetic bearings suspend the spindle by magnetic force to achieve high-precision and high-speed operation, but the cost is relatively high‌. ‌3.Cooling device‌: Since the CNC spindle motor generates a lot of heat when running at high speed, a cooling device is required to maintain a suitable working temperature. The cooling device ensures that the temperature of the spindle unit remains within a reasonable range to prevent performance degradation and damage caused by overheating. ‌4.Drive module‌: The drive module designed specifically for the spindle is responsible for accurately controlling the speed change function of the motor to ensure the stable operation of the spindle under different working conditions. ‌5.Sensor‌: The rear end of the spindle is equipped with a speed and angular displacement sensor, and the front end is designed with an inner tapered hole and end face to facilitate the installation and use of the tool.

4.Maintenance of CNC spindle motor ‌1.Cleaning and maintenance‌: Keeping the electric spindle clean is the key. Cleaning work should include cleaning of the outer surface and the inside, especially the airtight parts, which need to be cleaned regularly with detergent to ensure normal operation. In addition, cleaning of the cooling fan or air duct is also very important to ensure sufficient cooling of the spindle. ‌2.Lubrication maintenance‌: Reasonable lubrication can reduce the friction and wear of the electric spindle and extend its service life. Check the oil level and oil quality of the lubricator, change the lubricating oil regularly, and keep the lubrication system unobstructed and in good working condition. ‌3.Bearing inspection: The bearing is the part of the electric spindle that is most prone to failure, so bearing inspection is very necessary. Check whether the bearing has impurities, whether it is well lubricated, whether it is severely worn, etc. Once an abnormality is found, it needs to be replaced or repaired immediately to avoid safety hazards to the use of the machine tool. ‌4.Reasonable use: Avoid overload during use, eliminate impact loads, avoid long-term no-load work, etc., and reasonable use can effectively extend the life of the electric spindle. ‌5.Regular inspection: The axial runout and radial runout of the electric spindle need to be inspected regularly. For example, the axial runout of the electric spindle is generally required to be 0.002mm (2μm), and it is inspected twice a year; the radial runout of the inner cone hole is also 0.002mm (2μm), and it is inspected twice a year; the radial runout of the far end of the mandrel (250mm) is 0.012mm (12μm), and it is inspected twice a year. ‌6.Preventive maintenance: Perform preventive maintenance regularly based on the equipment usage and manufacturer's recommendations, such as replacing wearing parts and checking motor insulation performance. Preventive maintenance aims to prevent potential problems and ensure the normal operation of the equipment. ‌7.Fault maintenance: Maintenance performed when the equipment fails. This type of maintenance is usually performed after the equipment fails, with the aim of restoring the normal operation of the equipment as soon as possible.

Source:https://olgana.pixnet.net/blog/post/178552702

 Here’s everything you need to know about tractor information:

1. Types of Tractors

There are various types of tractors, each suited for different farming needs:

2WD (Two-Wheel Drive) Tractors: These tractors have power delivered to only the rear wheels, making them ideal for flat terrain and light-duty work such as plowing, tilling, and mowing. They are generally more affordable and fuel-efficient.

4WD (Four-Wheel Drive) Tractors: These tractors provide power to all four wheels, offering superior traction and stability, making them suitable for uneven terrain, wet fields, and heavy-duty tasks like hauling and plowing. They are more expensive but provide better performance in challenging conditions.

Compact Tractors: Smaller in size and ideal for smaller farms, compact tractors are great for tasks like landscaping, gardening, and light agricultural work. They often come with versatile attachments like mowers, loaders, and snow plows.

Utility Tractors: These are larger tractors designed for various tasks on medium to large farms. They are equipped to handle a wide range of implements and attachments and are commonly used for tilling, sowing, and hauling.

2. Key Tractor Features

When choosing a tractor, consider the following features:

Engine Power (Horsepower): Tractors range from 15 HP to over 100 HP, with larger tractors typically used for heavy-duty tasks. The horsepower needed depends on the size of your farm and the work you plan to do. Small farms may require tractors with 20-50 HP, while large-scale operations may require 70-100 HP or more.

Transmission: Tractors come with several types of transmissions:

Manual Transmission: Offers more control over gear shifting but requires skill and experience.

Hydrostatic Transmission: Provides smooth gear shifting with a foot pedal, making it easier for operators.

Power Shuttle Transmission: Allows quick shifting between forward and reverse, ideal for tasks that require frequent direction changes.

Approaching the Gungan City

STAR WARS EPISODE I: The Phantom Menace 00:13:42

The Importance of Quality Control in the Production of Stainless Steel Fittings

In the manufacturing industry, quality control plays a pivotal role in ensuring that products meet stringent standards, especially when it comes to stainless steel fittings. These components are integral to various sectors such as construction, automotive, marine, and aerospace, where safety, durability, and reliability are non-negotiable. For Jayant Rajendra Metal, a leading name in the stainless steel fittings industry, maintaining high-quality standards is critical to building trust with clients and ensuring product longevity. In this blog, we will explore the importance of quality control in the production of ss fittings manufacturer in India and how it impacts both manufacturers and end-users.

Quality control in stainless steel fittings production involves a series of processes designed to ensure that each product meets the required specifications for performance, safety, and durability. It starts from the selection of raw materials and continues through the entire manufacturing process, including forging, machining, polishing, and surface treatment. Stainless steel, known for its corrosion resistance, strength, and aesthetic appeal, is widely used in fittings due to these attributes. However, the performance of ss fittings manufacturer in India can be compromised if quality control measures are not strictly followed.

One of the first steps in quality control is the careful selection of raw materials. Stainless steel comes in various grades, such as 304, 316, and 321, each with different properties suited to specific environments. The quality of the steel used directly impacts the performance of the fittings. For instance, fittings made from 304 stainless steel are ideal for general purposes, but for environments that are more corrosive, such as marine applications, 316-grade stainless steel is preferred due to its higher corrosion resistance. At Jayant Rajendra Metal, sourcing high-grade raw materials is a top priority to ensure that the fittings meet the industry’s demands for durability and strength.

During the manufacturing process, precision is crucial. Stainless steel fittings undergo various processes such as forging, welding, and machining, all of which require careful monitoring. Forging must be done at the correct temperature to prevent structural weaknesses in the material. Similarly, welding processes should be controlled to avoid defects such as porosity or cracks, which can lead to product failure in the field. High-quality control standards ensure that each fitting is machined to the exact specifications required by the application, reducing the risk of failure in critical environments.

In addition to physical strength and durability, surface finishing is an important aspect of quality control. ss fittings manufacturer in India are often exposed to harsh conditions, whether it’s chemicals in industrial processes or saltwater in marine environments. A proper surface finish not only improves the aesthetic appeal but also enhances corrosion resistance. Quality control at Jayant Rajendra Metal ensures that the fittings are polished and treated to withstand various environmental factors, providing long-term performance and reducing maintenance costs for users.

Testing is another vital part of quality control. Various tests are conducted to ensure the fittings can handle the pressure, temperature, and environmental stresses they will face in real-world applications. For example, hydrostatic testing is commonly used to check for leaks, while tensile tests measure the material’s strength. These rigorous testing procedures help prevent failures that could lead to costly downtime or even dangerous situations in industries such as oil and gas or chemical processing. At Jayant Rajendra Metal, these tests are conducted with precision to ensure that each product performs reliably under the toughest conditions.

Quality control also plays a key role in regulatory compliance. Various industries have strict standards and certifications that manufacturers must meet to sell their products. For instance, stainless steel fittings used in food processing must meet sanitary requirements, while those used in the petrochemical industry must adhere to high-pressure tolerance standards. By maintaining strict quality control protocols, Jayant Rajendra Metal ensures that its products comply with industry regulations, giving customers confidence that the fittings are safe, reliable, and fit for purpose.

In conclusion, the importance of quality control in the production of ss fittings manufacturer in India cannot be overstated. For Jayant Rajendra Metal, adhering to the highest standards of quality control is essential to producing fittings that meet the diverse needs of industries worldwide. From selecting premium raw materials to monitoring each stage of production and conducting rigorous testing, every step in the process is designed to ensure that the final product is strong, durable, and reliable. This commitment to quality not only enhances the reputation of the manufacturer but also provides peace of mind to customers, knowing that they are investing in products that will perform well over the long term.

To Know More https://jayantrajendrametal.com/stainless-steel-fasteners-manufacturers-in-mumbai-india/

Fluid Mechanics for Mechanical Engineers - Read More | Arya College

Fluid mechanics is a fundamental branch of physics and engineering that deals with the behavior of fluids (liquids and gases) and the forces acting upon them it is taught by the Best Engineering College of Jaipur that is Arya College of Engineering & I.T. This discipline is crucial in various fields, including mechanical, aerospace, civil, chemical, and biomedical engineering. The study of fluid mechanics can be divided into two main areas: fluid statics, which examines fluids at rest, and fluid dynamics, which focuses on fluids in motion. This comprehensive overview will explore the principles, applications, and innovations in fluid mechanics, highlighting its significance in mechanical engineering.

Principles of Fluid Mechanics

Fluid Statics

Fluid statics, or hydrostatics, studies the conditions under which fluids remain at rest. It addresses concepts such as pressure variation within a fluid and the forces exerted on submerged surfaces. Key principles include:

Pascal’s Law: This principle states that pressure applied to a confined fluid is transmitted undiminished in all directions throughout the fluid. This concept is foundational for hydraulic systems, where small forces can create large movements.

Archimedes’ Principle: This principle explains buoyancy, stating that a body submerged in a fluid experiences an upward force equal to the weight of the fluid it displaces. This principle is critical in designing ships, submarines, and other floating structures.

Fluid Dynamics

Fluid dynamics investigates the behavior of fluids in motion and encompasses various phenomena, including flow patterns, turbulence, and viscosity. Important concepts include:

Continuity Equation: This equation expresses the principle of conservation of mass in fluid flow, stating that the mass flow rate must remain constant from one cross-section of a pipe to another.

Bernoulli’s Equation: This equation relates pressure, velocity, and elevation in a flowing fluid. It is instrumental in applications such as airfoil design, where the lift generated by an aircraft wing is analyzed.

Navier-Stokes Equations: These fundamental equations describe the motion of fluid substances and are essential for modeling complex fluid flows, including turbulence and viscous effects.

Applications of Fluid Mechanics

Fluid mechanics has a wide range of applications across various engineering disciplines:

Mechanical Engineering

Mechanical engineers utilize fluid mechanics principles in designing systems such as:

Pumps and Compressors: Understanding fluid flow is crucial for optimizing the performance of pumps and compressors used in various industrial applications.

Heating and Air Conditioning Systems: Fluid mechanics principles help in designing efficient HVAC systems that ensure optimal thermal comfort in buildings.

Aerospace Engineering

In aerospace engineering, fluid mechanics is vital for:

Aerodynamics: Engineers analyze airflow over aircraft wings and fuselages to optimize lift and minimize drag, ensuring efficient flight performance.

Propulsion Systems: The design of jet engines and rocket propulsion systems relies heavily on fluid dynamics to maximize thrust and fuel efficiency.

Civil Engineering

Civil engineers apply fluid mechanics in:

Hydraulic Structures: Designing dams, levees, and flood control systems requires an understanding of fluid behavior to ensure stability and safety.

Water Treatment Systems: Fluid mechanics principles are used to design effective systems for treating and distributing water.

Biomedical Engineering

In biomedical applications, fluid mechanics plays a role in:

Blood Flow Analysis: Understanding blood flow dynamics is crucial for designing medical devices such as stents and artificial heart valves.

Drug Delivery Systems: Engineers design systems that optimize the delivery of medications through various fluid mechanisms.

Innovations and Future Directions

Recent advancements in fluid mechanics are driven by technological innovations and computational methods:

Computational Fluid Dynamics (CFD)

CFD has revolutionized the study of fluid mechanics by allowing engineers to simulate fluid flow and analyze complex systems using numerical methods. This technology enables:

Enhanced Design Processes: Engineers can test and optimize designs virtually, reducing the need for costly physical prototypes.

Real-Time Analysis: CFD tools can provide real-time insights into fluid behavior, aiding in decision-making during the design and operational phases.

Smart Materials and Systems

The integration of smart materials in fluid mechanics is leading to the development of responsive systems that can adapt to changing flow conditions. These innovations include:

Self-Healing Materials: Materials that can repair themselves when damaged, enhancing the durability of fluid systems.

Active Flow Control: Systems that can actively manipulate fluid flow using sensors and actuators to improve performance and efficiency.

Multiphase Flow Studies

Research in multiphase flows, where multiple fluid phases interact, is expanding. Applications range from oil and gas extraction to chemical processing, where understanding the dynamics of different phases is crucial for optimizing production processes.

Conclusion

Fluid mechanics is an essential discipline within mechanical engineering, providing the foundation for understanding and manipulating fluid behavior in various applications. From traditional engineering practices to cutting-edge innovations in computational methods and smart materials, the field continues to evolve, driving advancements that enhance efficiency, safety, and performance across multiple industries. As engineers navigate the complexities of fluid behavior, the integration of new technologies will further expand the horizons of what is possible in mechanical engineering and beyond.

A Guide to Diverse Level Sensors for Point and Continuous Measurement

Accurate and reliable level measurement is essential for delivering efficacy, safety, and optimal performance in the dynamic world of industrial processes and automation. Because they offer solutions for both spot level detection and continuous level monitoring in a range of applications, level sensors are crucial in this field. In this article, we explore the world of sensors and look at the many types that are available, including capacitive, hydrostatic, optical, ultrasonic, potentiometric, and point sensors. Sensors of Levels

Point Level Sensors: These sensors are intended to identify a particular level within a container at a specific point. When the substance reaches a set level, these sensors offer binary feedback. Detecting high or low levels in tanks, silos, and hoppers are common uses. In point level sensing applications, accuracy and precision are essential for providing a prompt and precise response to varying levels.

Level Sensors: In general terms, include a range of designs and technology that serve various contexts and industries. These sensors keep track of the fluid or substance level in a vessel constantly and report the results in real time. They are essential for preserving steady levels, avoiding overflow or run-dry conditions, and streamlining procedures.

Capacitive Point Level Sensors: Capacitive point sensors are useful for detecting a variety of materials, such as liquids, powders, and granular particles, because they operate on the concept of capacitance. Since these sensors provide non-contact sensing, they are perfect for uses where direct contact can be hazardous or impractical.

Optical Point Level Sensors:  depend on a light beam’s interruption to determine if a substance is present or absent at a given level. These sensors are useful in sectors like the food and pharmaceutical industries where sensitivity and precision are crucial.

Potentiometric Level Sensors: Potentiometric level sensors use an electrical signal to represent mechanical displacement in order to determine a substance’s level. These sensors are an affordable option for many businesses due to their affordability, dependability, and compatibility for a wide range of liquids.

Hydrostatic Level Sensors: These sensors measure the pressure at the bottom of the container to calculate the liquid level, based on the principle of hydrostatic pressure. In places like water treatment facilities and industrial tanks, where excellent accuracy and stability are essential, hydrostatic level sensors are commonly utilized.

Ultrasonic Level Sensors: Sound waves are used by ultrasonic level sensors to gauge the separation between the sensor and the surface of the substance. Because of their versatility, these sensors can be used in a wide range of industries, such as bulk material handling, chemical processing, and wastewater treatment.

Conclusion:

In conclusion, selecting the right level sensor is essential to ensuring that industrial processes operate smoothly. Capacitive, optical, potentiometric, hydrostatic, and ultrasonic sensors are just a few of the many types of sensors that are available. These sensors can be used for point level detection or continuous level measurement, among other uses. As industries evolve, the integration of these sensors will be critical to optimizing efficiency, ensuring security, and improving the efficacy of several activities.

Deformation of hydrogel used to measure the negative pressure of water

Water, unexpectedly, has the potential to withstand a massive stretching force or tension due to its internal cohesive force. Under extreme tension, the hydrostatic pressure of the water would display as absolute negative. The comprehension of such a unique thermodynamic non-equilibrium state in the phase diagram of water is still blurry, which has sparked a lot of curiosity in the field. Nevertheless, after botanists discovered it in the xylem of trees first, this so-called negative pressure of stretched water could be designed to generate extremely large pressure differences. It has been employed in a series of advanced heat and mass transfer applications, including the on-chip synthetic tree for continuous water extraction, nanoporous membranes with ultrahigh interfacial heat fluxes, and so on.

Read more.

 so @grumpyoldsnake ​ asked me what core injury and healing looks like, and it was a good opportunity to finally nail down the details and draw a quick demo! Sorry Red, I needed a test subject. More details under the cut. 

Their skin is made of either silicone rubber, or a substance very similar to it, so it’s pretty heat resistant (good when your species used to frequently re-enter the planet’s atmosphere after lunch from a nearby asteroid). It's also more resistant to rips and tearing. 

Then you have their sensory/nervous system. Inside their body, it’s a semi-liquid black goo, and hardens into a gel outside (like their eyes). Visible here is mostly just the layer below their skin that senses touch, heat, and EM fields, but its  present practically everywhere. 

The next few layers vary depending on the body part, but usually you’ll have at least some section of material/reserve storage (to use in shapeshifting, healing, and replenishing their generator) that also houses blood pathways and other organs. Speaking of blood, cores only need oxygen as fuel for their furnace stomachs when they are digesting, so they don’t just have blood going everywhere in their body, and the ‘veins’ are also by default closed and empty.  They have a little pouch beside their stomach where they keep some oxygenated blood. Their ‘blood’ is also used to help carry additional materials to the needed sites when healing or shapeshifting. It’s clear or light pink in their body, and amber gold when oxygenated. 

What is very important to their frame’s upkeep is their electrolyte gel: it’s what moves current and voltage from their core around their body. It’s surrounded by various layers of materials that serve as electrodes and regulators. 

Finally, the grey/metallic parts are their frame’s support and movement systems, providing both the actual ‘skeleton’ and the actuators and hydraulics that move it. They’re very similar looking, and cores don’t really have a notion of separate ‘muscles’ and ‘bones’. For flexible things like antennae or grasping limbs/tentacles, hydrostatic semi-liquid metal ‘muscles’ are used.

While all cores technically have the capacity to shapeshift, and all can heal any frame injury with enough time and materials, a core’s personal skill at shapeshifting and energy manipulation will greatly affect healing speed. Red here is an outlier and can heal and shapeshift stupidly fast, growing his head back in a few seconds, provided he has enough resources. Most other cores will have to spend a few hours to a few weeks in a regenerative tank. Doing it this quickly makes him tired though, and doing it 3 or 4 times in a row means he’ll feel exhausted and will have to spend a few hours in the regen tank too.

Do's and Dont's of Old Farm House Basements

For some people, basements are pretty scary and I do not blame people who feel that way. They come with a completely different set of problems than just having a crawl space, especially when your house is 120 years old like mine.

Let's talk about what a good foundation looks like.

For anyone who wants to embark on their own home renovation journey and is about to buy a house, these tips will be essential for making good decisions and when to run like hell. Maybe you already own a house, some of these tips will still be helpful to you. Keep reading for all this good info, but don't forget to follow me for more DIY crafting and house renovation projects as well as tons of useful info!

Don't buy a house with concave basement walls

Don't buy a house with concave basement walls

This is a run like hell moment. If your foundation looks like it's pushing in or pushing out, that's a really expensive job to fix it, like thousands of dollars. Generally, this is caused by hydrostatic pressure build up which pushes in on the walls.

Do ignore efflorescence - it's not mold

The picture above is actually from my own basement. That white patch you see? Efflorescence. It's a build up of minerals from water that seeps through the porous sandstone. It's not harmful, but it does indicate that some water redirection could be done around the foundation. However, sandstone will inevitably always absorb moisture so this isn't going away soon, but it's not harmful so it. shouldn't scare you off.

Do check the grout between the stones.

Old field stone foundations like mine will need to be repointed. You will want to stick your fingers between the stones and pick at the grout to see how much of it is loose. If it's really bad, there will already be gaps between many of the stones. This is not the end of the world, but it does affect the structural integrity of the house. I paid a mason to come in and repoint my foundation from the interior, as well as my chimneys for $1,800. They also painted the stone to help will humidity issues caused from the porous sandstone. It's also a pretty easy and cheap job to do yourself if you have the time!

Don't plan on finishing the basement how it is

Did you know that prior to the 90's, no basement was every designed to be 'finished'? That means, if you really want to finish your basement, updated drainage around the base and exterior needs to happen before. Depending on the age and materials used to construct your basement, cost wise it might not be feasible to properly finish your basement. Let's say you skip that step and finish. it anyway. You run the risk of any items in your basement being destroyed either by high amounts of humidity, which causes mold, or through a flood. Even if your property has never flooded, you should always expect the worst. My cousin bought a house with a semi-finished basement that had never flooded. It took one torrential downpour that flooded the entire city for his belongings to all be destroyed.

Do inspect the condition of the joists.

Your joist generally sit on your foundation wall and run to a main beam, or to another foundation wall. In old homes like my own, it was not uncommon to notch the joists so that they would sit nicely on the foundation or in the beam. This was used in lieu of the braces/brackets we use today. The issue with this is that it decreased the effective depth of the joist since the underside is unsupported. In areas of the house that have heavy objects, or load bearing walls, one can observe these joists start to split at the notching point. It's not the end of the world, but you should plan on lifting the joist with a bottle jack, putting in a brace with nails (NOT screws! They do not have the sheer strength!). This increases the strength of your joist significantly and will prevent further cracking!

The other thing you will want to check is how level the joists are. My house is very unlevel compared to new builds, but not unreasonably so. The decreased strength and long joist runs have caused bowing in my joists. I've just made sure they're fully supported moving forward while I level out the house so they have the strength to hold new additions!

Don't buy a house with many massive holes through joists and the sill plate

The picture above is once again from my own basement after a repair had been made (Yes, I used screws in the brackets, I have to go back with nails and fix it... I blame my dad 🙃). The plumber who put in the stack behind the new wood, just decided to cut off a joist and leave it completely unsupported. I can't believe anyone in their right mind would just leave a joist unsupported like that... Don't do that. But behind the stack, is part of my sill plate, which is pretty well irreparable at his point because of all the holes cut into it for pipe. For small pipe or electric, cutting a hole in the bottom 1/4ish of a joist or sill plate is fine, but making large holes destroys the structural integrity of your home. That's because it's the depth of the wood that gives the strength to hold up your home. These are repairable, so it's not the end of the world, but it does take some knowledge and time. Epoxy, sistering, and scabbing are all methods used to repair joists and sill plates. However, I would run if you see any major house sagging or other noticeable problems caused through this type of damage.

Don't buy a house with abundant moisture problems

Moisture causes mold, but the mold shouldn't scare you, even if it's black mold, as long as you can control the moisture. One, mold does not have to be black to send out mycotoxins so black mold isn't the only enemy. Two, mold is harmless with insufficient moisture. Mold needs a food source, like wood or drywall paper, plus water to grow. The truth is, mold is always present in every home whether you like it or not. Whether it's active is another thing. My house is over 100 years old, IT HAS MOLD. All that mold is super inactive because no water is leaking and I have a dehumidifier in my basement. So am I going to spend thousands of dollars to clean it up? Hell no. I'm going to invest in keeping my house dry and the mold won't affect the air quality. However, you shouldn't invest in a house that's going to be difficult to keep dry. My house is on top of a hill so I just have normal porous sandstone humidity issues which are pretty well controllable.

I feel like I covered some really important topics that are important to evaluating basement and foundation quality. I probably missed somethings, but I feel like these are the topics I've come across the most making improvements to my basement foundation and/or made me swear at the previous owners for doing really dumb things.

Have questions that I didn't answer here?

Hit that reblog button and type in your question! I'm sure someone else would find it equally as helpful.

Have your own helpful tips?

Pleaser add to this post! Reblog and add your useful information. Let's make basements less scary!!!

RIVALS: Thunder

Rivals Master List

-------------------------

a masaki ichijou x fem reader fic

Genre: action, romance Warnings: none! Word count: 2.6k+

-------------------------

“Shiba-san, I think I’m going to throw up.” 

You clutch the shoulder of Tatsuya Shiba, First High’s best technician and the one currently servicing your CAD. With a mildly concerned look, he steadies you and walks you to the stage riser. 

Around you, students hustle to and fro, working on computers, tinkering with CADs, and typing hastily on tablets—other technicians for First High. You see, it was the 2095 Nine Schools Magic Competition, and you, a bright-eyed magician hailing from a distant country, was chosen by your First High teachers and upperclassmen to represent the school for Ice Pillar Break. Not much surprise there—even amongst the Blooms students, you were considered one of the best: you learned ridiculously fast, your casting speed rivals that of Miyuki Shiba’s, and, although it wasn’t known to many, your Psion count was very, very high, making for a good starting set of talents for the flashy event. To top it off, you worked hard to keep your place in the prestigious school (one time, you had to explain to your Japanese classmates how and why you, a foreigner, topped the exam for Modern Japanese class). Unfortunately, though, your technical skills weren’t anything to write home about; you could barely calibrate a CAD to save your life. Well, that’s why you had Tatsuya with you.

“You’ll be fine. (L/N)-san. You just need to take your time.” Tatsuya reassures in his usual monotone voice. He pauses, as if thinking what to say, before adding, “Just don’t draw attention to your casting.”

Welp. Aside from the fact that it was your first match of the tournament, you were also horribly unlucky in that your opponent, Suzuki Mutsuba of Third High School, is the current shoo-in to champion Ice Pillar Break for the Newcomer’s Division. Her casting speed and aggressive tactics made her an extremely difficult opponent as she would be able to destroy the ice pillars quickly before you could even cast an offensive spell.

To overcome this, you and Tatsuya had agreed on using your speciality in Ancient Magic which would give you great burst damage and some stealth. It would, however, take a lot of time to cast, and so you had to constantly run a modern counter magic sequence to prevent getting slaughtered in the first couple of seconds while preparing for your Ancient Magic spell. The thought made you want to hurl your breakfast on Tatsuya’s shiny black shoes. 

“Thanks.” You smile weakly at him. “Well, if I lose today, at least I look cute.” Tatsuya, who, as expected, barely reacted, giving you a small smile. Well, it was true. Saegusa-senpai had insisted that the Ice Pillar Break event had also become a mini-fashion show in recent years, so she and some of the other female upperclassmen took a lot of pleasure in dressing you up. You wore a modernized version of your country’s traditional garb (“I absolutely insist! You’ll be a standout,” Saegusa-senpai exclaimed one time after a meeting, imploring you to send for traditional clothes), your face in light makeup, and your hair in a bun. You knew that with your outfit, you’d surely be a standout amongst the sea of competitors in kimono and hakama. 

To prevent yourself from throwing up, you had let go of Tatsuya and preoccupied yourself with fiddling with the stitching on your top, when a disembodied voice booms over the speakers in the holding room. “Mutsuba Suzuki, Third High School, versus (L/N) (F/N), First High School!”

You take a deep breath. You look back to your weeks of training: the tingle of electricity prickling your skin, the feeling of power dancing at the ends of your fingertips, the mental exhaustion from practicing deadly magic for hours on end. You remember the day you first boarded the plane for Japan at the behest of your government, scared that you wouldn’t make it in the suffocatingly competitive atmosphere of First High. You breathe in this moment now: you, who has made it this far and who will make it even further. Suddenly, you don’t feel like throwing up anymore.

“Go on and show them.” Tatsuya hands you your device, slender and silver, and your talisman, a pair of black gloves with a red inscription on the palm. You look into his blue eyes and see absolute certainty. In you, perhaps? There was no time to contemplate, so you take the device and put on the gloves, shooting him an eager grin as the platform begins to rise. “Yes, yes.”

You emerge into the light, your chin held high.

-------

“Oi, Masaki, it’s the foreigner girl!”

“Mm.” Masaki Ichijou, scion of the Ichijou clan and freshman ace of Third High School, looks up from his device to George and then to you at the center of the stadium. You were something of a spectacle at this year’s Nine Magic High Schools Competition, because foreigners were so rare at magic high schools, much less at a contest of Japan’s best up-and-coming magicians.

You emerge from the riser, your stance self-assured. Judging from the large screen flashing yours and Mutsuba-san’s faces, Masaki thought you were pretty, yes, but not in that demure Japanese way. Your wide eyes were intense and serious but a little restless and some strands of your (H/C) hair loose from your bun were fluttering in the wind. You were wearing some sort of unique outfit; probably from your home country, Masaki notes, and a pair of gloves. He eyes the CAD in your hand. General-type. General-type CADs can hold a lot of Activation Sequences, but it’s taxing for the caster. You using one meant you have some skill. 

“Ooh. General-type CAD. Still, she doesn’t look particularly tough.” George pulls out his phone and starts typing furiously. “Do you think I should still have the others take stats?”

Masaki was certain you weren’t a lightweight: after all, your home country sent you to First for a reason, and First sent you to this competition. First High is not a school to be taken lightly. He nodded. “Yes. Just to be sure.”

Still, as good as you may be, Mutsuba-san was probably better, Masaki thought. “But I don’t think she can win against Mutsuba-san,” He adds. “She tied with me in practice once or twice, you know.” 

George nods slightly. “Yes. Her control and cast speed are above average. And her specialty really is suited for this—“

The siren sounds, cutting off George and shushing the crowd. It’s time. After two counts, a screeching noise fills the air, and the match between First High and Third High begins. 

On the far right, Mutsuba-san, dressed in a pink kimono, outstretches a gun-shaped CAD and begins her offense. Masaki knows what it is from his practice matches with her: Phonon Maser, an A-rank spell. A bright beam bursts forth from the barrel of her CAD and vaporizes one of your pillars. Masaki’s eyes dash to the left of the field. You wince a little, your left hand gripping your CAD tighter and your right hand tucked behind your back, but you quickly resume your steady gaze and continue casting. A sequence forms over your pillars and a dull light begins to pulse over your own ice field. Soon, Mutsuba-san’s Phonon Maser only makes dents. 

“Data Fortification.” George makes a yawning motion. “Effective, but boring.” 

“Hey! I use Data Fortification.” Masaki says indignantly. “And her defense is decent.”

Third’s best engineer regards his friend dryly. “Mm. But it’s not your only spell. Miss First here isn’t even attempting an offense.” He gestures to the field. He was right. You were holding your CAD high over the ice field, as if commanding them to stay frozen—and they did for the most part, receiving Mutsuba-san’s onslaught of lasers relatively well. Still, Masaki thought, you weren’t making any moves to destroy Mutsuba-san’s pillars. 

“Yeah. As good as she is at defending herself, it’s useless if she doesn’t attack.” George nods in reply. 

A few more seconds of the standoff between you and your opponent pass. The young Ichijou takes a quick glance around. George looked like he was getting more bored with each passing second, and he wasn’t the only one losing interest. Many other Third students in the stand who waited eagerly for you a couple of seconds ago now whisper impatiently amongst themselves, bored and unimpressed by the seemingly one-sided battle. To Masaki’s right field of view, the First High students in their stand shift uncomfortably in their seats, visibly worried about the outcome of the match. It seemed that even they didn’t know what was going on. 

Masaki fixes his attention back on you who still kept up with your ironclad defense. Why did First High even bother to send someone who won’t attack, Masaki wonders. He tries searching your face, your figure, your magic for any indication of anxiety, uncertainty, or whatever one was supposed to feel whenever they were about to lose a match. With your steady gaze, (E/C) eyes fixed on the field before you, your defense magic constant in its impenetrability, you seemed too calm for someone about to lose, Masaki observes. And then it hit him. 

“It’s not calmness.” He murmurs.

“What?” George gazes at Masaki quizzically. With all their years of friendship, George has pretty much gotten used to his best friend’s mutterings, especially during training—he’s heard I have to get this perfectly or I need to adjust the hydrostatic pressure far too many times in simulations—and even learned to take some of them seriously. He’s written them off as telltale marks of a genius (because he himself does the same things when he’s zoning out in his lab).  

“She’s waiting for something.” It’s not calmness, Masaki thought. It was something more predatory. Staring at your face on the megascreen, he realizes that you, in all your non-aggression, were fighting back a smile. 

Prompted by Masaki’s fixation, George studies your figure with the I-discovered-a-new-Cardinal-Code look on his face, the look he uses when scrutinizing a research article or examining Akane’s new outfit (It’s a well-known fact that they like each other. Masaki long ago conceded to the fact that his live-in best friend and his younger sister Akane are practically dating.) As George looks over you, his eyes widen. “Look at her right hand.” 

“Huh.” Masaki studies your right arm tucked away behind your back, away from everyone’s attention. Your hand, covered by your glove with the red seal on the palm, was making some sort of small, rapid fingering motion, like you were weaving a thread or plucking multiple strings on an instrument. It was so slight and so seemingly random that even the announcers and Mutsuba-san did not even recognize. 

Masaki raises an eyebrow. “That’s Ancient Magic, isn’t it?” 

“Yeah. Her glove is the talisman.” George leans back in his seat and crosses his arms, as if waiting for something to unfold. As he did, he glances up at the sky. He then grips Masaki’s shoulder tightly.

The young Ichijou tries to slap his best friend’s hand off. “Hey, you’re going to ruin my uniform.” 

George didn’t seem to hear him. His gaze, now bewildered, was fixated on the sky. “By Kami-sama...” He whispers. 

Masaki glances up with him. The sky was dark, much darker than it was minutes ago. Clouds seemed to form quickly, almost too quickly, overhead. George‘s grip on Masaki’s shoulder tightened. “Masaki, don’t watch the field, she’s casting a—“

Before he could finish his sentence, you whip out your right hand and snap your finger. A streak of pure white floods everyone’s vision and a deafening clap thunders overhead. The stadium erupts in surprised yelps from the audience. The light soon disappears, revealing you standing there on your podium, gloved right hand outstretched and a wide grin spread over your face. 

Masaki hastily surveys the field, rubbing his eyes from the sudden flash of lightning. Half of Mutsuba-san’s pillars had exploded, boiling hot water sizzling on the grass around the ice field. The other half were melted to varying degrees. The ground underneath what used to be the center pillar, where the light struck, was scorched. 

“Well, well.” He clicks his tongue in amazement. “Thunder Cloud.” 

George’s red eyes widened. “That’s…that’s the A-class Ancient Magic that copies the natural lightning generation process...” 

“Yes.” Masaki let out a sigh. He’s seen the spell before when his father worked with foreign magicians from the tropical southern regions of the Asian Union, but he’s never seen them do the little motions you did. “Father used to know a few who could cast it. They literally create cumulonimbus clouds and separate the electrons in such a way to make the lightning strike an exact point. It takes a lot of Psions but it’s highly lethal. To cast it while casting a modern spell...”

George started typing on his phone furiously. “That’s next-level. Gotta have the team take note of this.” Masaki could only nod in reply. “Now that’s why First sent her.”

Mutsuba-san looked shocked that she only had half her pillars left within a fraction of a second and scrambled to cast a defensive spell, to no avail. You had already snapped your finger again, causing a large Sequence to form in the sky, and lightning strikes the pillars, this time stronger, brighter, and hotter than the last. 

The pair manage to just avert their eyes in time. There were deafeaning cheers on the right side of the stadium—probably First audience—and then they were drowned out by a crack of thunder like a whip. When the light cleared, there was nothing left of Mutsuba-san’s pillars, just the scorched ground upon which they once stood and steam rising from her side of the field. All ice and water had been vaporized.

The siren screeched loudly. “The match goes to (L/N) (F/N) of First High School!” 

The stadium erupts in cheers, except for the pair’s stand, which consisted of Third students. Third High sat in stunned silence. No one had expected that you would defeat Mutsuba Suzuki, a member of the Ten Master Clans and a favorite to win the Newcomers’ Division for Ice Pillar Break in a complete wipeout. And in such a rapid and unexpected way, too.

George clicks his tongue in amazement. “Now, that’s one way to get everyone’s attention.”

“And the Clans’ attention, too.” Masaki says in a soft voice.

George glances at him and raises an eyebrow, a playful smile on his face. “Could it be that the great and super-single Ichijou Masaki is expressing his interest?”

Masaki glares at him incredulously and rolls his eyes. “Yes, George, I am extremely interested in this girl whom I’ve never met and whose background I have no idea about. What I’m saying is that defeating a member of the Master Clans is—“

The star engineer lets out a small chuckle. “Yes, yes, I know what you mean. Still…you never know, right?” 

Masaki exhales loudly through his nose. “I know a lot of things, George.” He takes a quick glance back at the megascreen, which shows you practically beaming as you wave at the First High crowd, as if you didn’t just cast very taxing and very deadly magic seconds ago. ‘(L/N) (F/N)’, it says on the screen. He thinks of you, you in the moment, smiling with the thunder. He tries to speak your name in his head, pronouncing the individual syllables the way he’s heard people speak names of your descent, seeing how each sound would fit in his mouth. At the back of his mind, he thinks it fits well, but he keeps this information to himself.

George didn’t seem to notice his best friend’s thoughts wandering. “Uh-huh. Well, I should go check on Mutsuba-san’s hardware. Catch you later.” He moves towards the exit with the leaving crowd but pauses at a notification from his phone. He scans it, eyes widening for what seemed like the hundredth time in the past couple of minutes. 

”What is it?” Masaki asks, just barely having snapped out of his reverie of you.

George turns to him, a wicked grin on his face. “Just got word from the team. She’s going to sub for Monolith Code.”

-------------------------

Next: Spark I

My Interstellar QUANTUM [iQ] HARRELL TECH [iQHT] SPIRIT MILITARY.gov [iNWO] ILLUMINATI of Ancient LEMURIA [MU]… Mysteriously PILOT Our Highly Classified… U.S. Ancient [USA = PREHISTORIC] Ægyptian American [ATLANTEAN] UFO Pentagon Military MOTHERSHIP from Astronomical NIBIRU [MAN] on July 30, 2021 [V]… Using QHT's Highly Complex [ADVANCED] Ancient SUBTERRANEAN Earth Archipelago [SEA] CLOUD Coordinates that METALLURGICALLY ACCELERATE NANO [MAN] BIOTECHNOLOGICAL Human AVATAR [HA = HARRELL] OBJECTS HIGH UP IN DA’ SKY… within the Cloud Infrastructure of ABORIGINAL [CIA] Human Compu_TAH [PTAH] Logistic Configurations POWERING Computerized [PC] MOTHERBOARDS of SIRIUS Thermal Infrared Energy [HEAT] Human DYNAMICS & MOTIONS [BIOMECHANICS] Electromagnetically GENERATING… MOOR Rapid Oscillating Magnetic [ROM] Wave Fields [RADIATION] of Highly Complex [ADVANCED] Ancient Cosmic Algorithmic [CA] Computational [Compton] STAR Mathematics ENGINEERING [ME = U.S. Michael Harrell = TUT = JAH] SIRIUS Stoichiometric Chemical Equations from the Quantified [EQ] Multiplication of Associative & Commutative [MAC] PROPERTIES… Creating [PC] MAGNETIC FORCES of EXTRATERRESTRIAL Energy Life [FEEL] POWERS… Immaculately MATERIALIZING [I’M] from Inner Earth’s [HADES] OCCULTED [HIDDEN] Subatomic Oceanic Floor Particles of Archaean [PA] Earth Metals of Primordially ANCIENT [PA = SUPERNATURAL] Bioluminescence & Chemiluminescence Elements [BCE] Pressurized by Our Supernova Nucleosynthesis during the Sequential Hydrostatic Burning Processes of Thermonuclear Proton Energies Forming NANOSCOPIC Covalent Bonds of Highly Complex [ADVANCED] Cycloalkynes Isolated by the Organic Electron Field of Subatomic Earth SUN & MOON Energies [ME = U.S. Michael Harrell = TUT = JAH]… that Energetically TELEPORT [JET] ME [iTUT®] 2 the Back of Our OCCULTED [HIDDEN] MOON Universe [MU] of Astronomical NIBIRU [MAN]... Celestially Located DEEP IN:side My Intergalactic MAGNETOSPHERE [I'M] of SIRIUS B [BETELGEUSE] Constellation [B.C.] STARS... who IMPERIALLY Established Our Biblically Ancient [BABYLONIAN] Interplanetary Human GODS [EXTRATERRESTRIALS] from ORION’S 9th Human SOUL Dimension of Interstellar Luz ATLANTIS [iLA] 🛸🛸🛸 (at San Diego, California) https://www.instagram.com/p/CSiBnasJvQ7/?utm_medium=tumblr