Some Thermal Shock stuffs

First time I’ve doodled the lad in a while, some slight changes but I’m still fond of his design.

I also made some NES mock-ups for fun because I suddenly thought “what if a Thermal Shock game was like Mega Man, but your bullets freeze enemies like the Ice/Freeze ability in Kirby’s Adventure? What if you could then kick them around?” and high school-me crawled from the shadows and possessed me for an hour or two to make these images. That’s about all I can contribute to a game, though, I’ve still got a comic to draw!!

Sell Circuit breakers in San Diego CA

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A Brief Introduction to Kyanite

Kyanite is a kind of natural refractory raw material mineral with high refractoriness and high temperature volume expansion.There are parallel stripes on the crystal face. Color is light blue or cyan, bright gray and so on.It is a high alumina mineral.

Chemical composition: Al2O3 63.1%, SiO2 36.9%.Single crystals are often long plates or blades parallel to (100).Naturally produced kyanite is often close to the ideal composition.Its strong resistance to chemical corrosion, thermal shock mechanical strength, thermal expansion irreversible.It is the main raw material for the production of amorphous material, electric furnace top brick, phosphate unfired brick, mullite brick and low creep brick.It is also a metamorphic mineral, occurring mainly in regional metamorphic crystalline schists, whose metamorphic facies range from greenschist facies to amphibolite facies.Also commonly used as diamond ring face, bracelet, necklace.Switzerland and Austria are famous producing areas.

Mineral deposit profile

The English name kyanite, derived from the Greek kyanos, refers to the most common color of kyanite.It is an insular silicate mineral, composed of Al2[SIO4]O. And andalusite, silanite homogeneity.Belongs to the triclinic crystal system, the crystal is flat strip, often columnar crystal shape, visible double crystal.Sometimes they form radial aggregates.The colors are blue, bluish white, cyan.With {100} complete and {010} moderate cleavage.Hardness has obvious anisotropy, so it is also known as two hard stone.The Mohs hardness is 4.5 in parallel crystal elongation direction, 6 in vertical direction, and the specific gravity is 3.53 ~ 3.65.The 435nm and 445nm absorption bands are visible.Regional metamorphic products occurring in crystalline schist and gneiss.When heated to 1300℃, kyanite into mullite, is a senior refractory material.Aluminum can also be extracted.

A bright transparent crystal used as a precious stone, preferably dark blue.North Carolina has a deep blue, green gem cyanite. Crystals can be ground into faceted gems or beads, but are difficult to polish and polish.

The main components of kyanite minerals are kyanite and a small amount of sillimanite, the accessory mineral components are quartz, and the secondary minerals are biotite, gold mica and chlorite.

The theoretical composition of kyanite is 62.93% and 37.07%. Because the cyanite mineral crystal often contains a small amount of accessory mineral components, so under normal circumstances the content is not up to the theoretical value.For the concentrate of kyanite mineral, its content is the sum of kyanite and impurity minerals.

Kyanite is one of the typical regional metamorphic minerals, mostly from argillaceous rock metamorphism.It is mainly formed under high pressure of intermediate metamorphism.It exists in regional metamorphic schist and gneiss and related crystalline granite and quartz dikes.Associated with garnet, crossstone, mica and quartz.

Place of origin

California, Iowa, Georgia;Canada, Ireland, France, Italy, Switzerland, India, Brazil, North Korea, Australia, etc.

Since the 1940s, when China began to investigate kyanite minerals, especially from the late 1970s to the early 1980s, a great deal of survey and exploration work has been carried out, and more than 20 kyanite mines have been discovered, distributed in over a dozen provinces and regions.Major ore deposits are distributed in Shuyang, Jiangsu Province; Yinshan, Henan Province; Xingtai, Hebei Province; Dianbusmiao, Inner Mongolia Province; Bulagai, Xinjiang Province; Fanzhi, Shanxi Province; Yuexi and Huoshan, Anhui Province; Dacaogou, Liaoning Province; Wenchuan, Sichuan Province; Hot Water Pond, Yunnan Province; Shansi, Jilin Province; Tanghekou, Yang County, Shaanxi Province.

The Importance of a Solar Panel Inspection | advancedsolartechnology.com.au

Whether you're a new homeowner or a long-time solar power user, it's vital to conduct a solar panel inspection once every 12 months. A solar panel inspection should be combined with a yearly cleaning to ensure they are in good condition. Additionally, you should have your panels inspected and cleaned after any significant weather events, such as high winds or rain. Even minor storms can cause significant damage to a solar panel system.

Thermal anomalies

Thermal anomalies are abnormalities that can be detected during a solar panel inspection. These can be caused by two common reasons. Firstly, they can be caused by erroneous connections or mismatching between PV modules. Secondly, they can be caused by internal PV module defects that may affect bypass circuits. Regardless of the cause, thermal anomalies should be investigated to determine whether your system is safe to use.

While thermal images are important in identifying hot spots, RGB photos are also useful in identifying them. In some cases, hot spots may be caused by bird droppings or plant-based debris. They can also be caused by physical elements such as electrical poles or high tension cables.

Electrical system

If you are planning on installing solar panels on your property, a comprehensive electrical system inspection is essential. The inspector should look for any signs of improper installation or deterioration. The condition of batteries is also an area of concern. Batteries are expensive and must be properly maintained. Since this is beyond the scope of a typical PV inspection, you should have a specialist evaluate them.

An electrical inspector will also check for proper grounding. Proper grounding is important for safety. Look for signs of new connections to the grounding electrode and visible conductors.

Fire safety

Fire safety is an important concern when inspecting solar panels. Solar panels can contain live energy that can cause fire hazards. To minimize the risk of fire, you should isolate the solar panels from the power grid and shut off the power supply. You should also have someone familiar with the solar panels and control systems to assist. Since solar panels are privately owned, the main utility company will not be able to access them.

The International Fire Code (IFC) addresses fire safety regulations for PV power systems, including solar panels. It also provides specific requirements for roof and ground-mounted solar systems. This code also provides detailed information on the proper design, installation, and inspection of solar equipment.

Grounding

Grounding is an important consideration during solar panel inspection. If it is not properly grounded, it can pose a significant safety risk. In order to prevent electrical shock and fire hazards, grounding must be properly installed. A bare copper wire used as an array ground wire should be at least #6 AWG. Smaller stranded wires may also be used. Metal conduit should also be grounded.

Before installing solar panels, it is vital to check the wiring and grounding of the panel. A grounding system will ensure that sudden electrical surges are diverted to the ground. This is essential because the earth does not conduct electricity well.

Home's structure

When installing solar panels, it is important to have an expert inspection of the home's structure. This inspection will ensure the panels are securely attached to the roof and meet electrical and building codes. It will also verify the proper grounding of the panels. The inspector will also look for signs of aging, including loose shingles, cracks and other signs of weather damage.

The first step in the process is to identify the electrical meter. This meter is usually located on the side of the home. Once the electrician finds it, he or she will measure and take pictures of the area. The electrical panel connection will run from the top of the home down to this area.

Costs

The cost of professional solar panel inspections varies based on the size and location of the solar panel array. For example, some arrays are on the rooftop, while others are mounted on the ground or side of a home. Larger solar panels require a more time-consuming inspection process. Also, some contractors will charge a minimum fee for a small array, while others will bundle cleaning and inspection services together.

Regardless of the size of your solar panel system, you may want to get your solar panels inspected once a year. Most inspections will run you about $150. In some cases, you may need a second inspection if you suspect a problem. Getting a solar panel inspected annually can save you hundreds of dollars over the lifetime of the system.

Drone inspections

Solar panel inspections can be done using drones for a variety of reasons. For one, drones can perform surveillance inspections and they can use thermal imaging to provide a thorough analysis of the panels. In addition, drones can be programmed to record UltraHD 4K video, which allows for the detection of heat failings in the panels.

Drones can also enhance the efficiency of the inspection process. They are highly versatile and can carry a variety of payloads that include thermal and RGB cameras. Thermal imaging is essential when examining solar panels. Combined with RGB imagery, this type of imaging can help engineers make critical decisions on how to properly operate the solar panels.

NASA Shows Off Psyche Spacecraft to Media Members of the media were invited to a clean room at JPL to interview mission leaders and see the asteroid-orbiting spacecraft before it ships to Florida for its August launch. Engineers are putting the final touches on NASA’s Psyche spacecraft, which is set to launch from Cape Canaveral, Florida, in August on its journey to a metal-rich asteroid of the same name. Members of the media got a chance to see the spacecraft up close in a clean room at the agency’s Jet Propulsion Laboratory on Monday, April 11. Reporters also interviewed mission leaders, including Psyche’s principal investigator, Lindy Elkins-Tanton from Arizona State University, and its project manager, Henry Stone from JPL. “Welcoming reporters into the clean room gives the public a glimpse of the years of hard work that have gone into this mission,” said Brian Bone, Psyche’s assembly, test, and launch operations manager at JPL. “Thanks to the Psyche team’s determination and skill, we’re in the final stretch of readying the spacecraft to head out to our launch site in Florida." To prevent the van-size spacecraft from bringing Earth bacteria into space, reporters wiped down their equipment with isopropyl alcohol and donned protective smocks and hair coverings before entering the High Bay 2 clean room in the Lab’s storied Spacecraft Assembly Facility. NASA is set to ship Psyche to the agency’s Kennedy Space Center in Florida for launch this summer. The spacecraft will fly by Mars for a gravity assist in May 2023 and, in early 2026, orbit around asteroid Psyche in the main asteroid belt between Mars and Jupiter. Scientists think the asteroid, which is about 173 miles (280 kilometers) at its widest point, may consist largely of metal from the core of a planetesimal, one of the building blocks of the rocky planets in our solar system: Mercury, Venus, Earth, and Mars. If so, it could provide a unique opportunity to study how planets like our own Earth formed. The mission has been in the phase known as assembly, test, and launch operations since March 2021. Optimal launch periods to the main asteroid belt are limited, so over the last year, the team has worked against the clock to complete assembly. They recently attached the largest solar arrays ever installed at JPL and have put the spacecraft through a series of rigorous tests to simulate the extreme conditions that a NASA spacecraft endures. After undergoing electromagnetic, thermal-vacuum, vibration, shock, and acoustic testing, Psyche has been cleared to proceed. The launch period opens Aug. 1. More About the Mission Arizona State University leads the Psyche mission. JPL, which is managed by Caltech for NASA, is responsible for the mission’s overall management, system engineering, integration and test, and mission operations. Maxar Technologies in Palo Alto, California, provided the high-power solar electric propulsion spacecraft chassis. JPL also is providing a technology demonstration instrument called Deep Space Optical Communications that will fly on Psyche in order to test high-data-rate laser communications that could be used by future NASA missions.

"It's an unremarkable world--well outside the major Brasque interstellar routes, in a patch of almost uninhabited space that's not affiliated with any of the big spacefaring powers. You wouldn't have heard of it. The star is called Rau Tamaize, after one of the minor signs in Kintean astrology. No? I didn't think so. The planet itself has no name, just a letter. Rau Tamaize c, if you want to look it up. We had to stay in orbit for a few weeks once, making repairs after an unfortunate encounter with the Olfarinn.

"They're called--well, I call them the sparrowflies. I don't think they have a proper name. Their body is about as long as your arm, sleek as an aircraft, with eyes the color of jewels. They're covered in a light fur that gets longer toward their tails, which are long and colorful, like feathered banners that extend behind them as they soar through the air. But their wings are most striking of all: enormous, gossamer-looking things, but fantastically strong despite how thin they are. They catch the light of Rau Tamaize and shatter it into thousands of pieces, and when they come out of the clouds, it's like fragments of a rainbow that's broken loose from a storm, and has been scattered into the air.

"Rau Tamaize c is a rocky world, with a thick atmosphere. Not quite a giant terrestrial, but the air pressure is far too high to be livable at the surface for any Augrin or Entaro. And too high for the sparrowflies themselves--they've adapted to live perpetually in the air, riding the currents of their homeworld's thick atmosphere. They rise on the morning thermals, and in the evening they slowly descend, circling the whole planet in no more than a few days. Probably thousands, or tens of thousands of times in a single lifetime. They're dancers, you know. They move through the air in complex patterns, at their highest and swiftest under the noon sun, when they rise to the very edge of the stratosphere.

"How did such a creature evolve? They're quite unlike anything else on their homeworld. I've investigated the matter closely, and there are hints in their biology--maybe they were genetically engineered. Maybe they're not even entirely organic. Maybe they're not even from that world. I was going to trap some--I had the rig set up on one of our runnercraft, to sidle up to a flock one evening as they were entering their somnolent phase, and snatch one or two out of the air. It was fortune, a miracle, really, that stopped me. Quite by chance, I discovered they were sentient. Not like you or I. Their cognition is entirely different. That's why I didn't notice at first. I still shudder to think of what would have happened if I hadn't noticed. Their language is exchanged by subtle electrical signals that jump from wingtip to wingtip as they approach one another. The lightest brush; the fine hairs that rise from the edge of the wing brush against one another, carefully modulate the signal. And by such signals, and by the forms and patterns they make dancing through the air, they converse, they tell stories, they speak of their journeys through the air.

"For the sparrowflies, stillness is death. They spend their whole life in motion, you see. They never land. They never alight, not on any mountaintop or high promontory. They rarely descend below the deepest clouds, and they regard the storm-covered land below as a place of darkness and fear. That is the place their beloved companions descend at last, when their wings beat no longer, when they can hold themselves aloft no more. To trap a sparrowfly--as I nearly did--would be a monstrous crime. It would be an unbearable torment, if it did not kill them instantly from the shock. Their bodies are made for motion. Their whole essence is centered around it. They are creatures of the air and freedom, who have never known, nor could ever understand, what it means to encounter a wall or a prison of any kind.

"They tell stories, did I mention that? Not much like ours. As I said, their cognition is very different. I'm not even sure if they have a strong sense of self, an identity apart from their flock. And their flocks merge and split and merge again--they are carried along together. But they do have something like stories. It took a long time, many weeks of maneuvering my little ship near them, showing them that I wasn't a danger, making careful measurements of the electric signals they sent to one another, recording their dances, and running everything through various interpretation filters again and again. After a while, I began to work out the rudiments of their communication. It is subtle, absurdly polyvalent, intricate, yet at the same time startlingly simple. They have millions of signs regarding the air, the sun, the color of the clouds, the rising and falling winds, and even the position of the stars. But they have few signs for emotions, almost none for what transpires within their minds, almost no notion of history and none at all of politics or science or law. Yet they know of other worlds. They know of the perpetual storms of Rau Tamaize b, the gas giant which shines in their evening sky, and the cold hydrocarbon winds of Rau Tamaize e. As I said, their biology is very unusual; it's not inconceivable to me that perhaps some ancestor of theirs discovered a way to ride the most diaphanous winds of their sun, and journeyed to other worlds, to bring back news of their skies.

"Here is a story of theirs, since you ask. It's by far their longest tale. It concerns two souls--lovers, perhaps, after the fashion of their people. Brightest-Star-of-Morning, and Light-of-the-Sun. Brightest-Star-of-Morning fell one day, beneath the clouds, beneath the world, and was lost to Light-of-the-Sun. And so piercing, so intolerable was Light-of-the-Sun's grief, they descended into the realm of the dead to seek Brightest-Star. To dark places and on dark winds Light-of-the-Sun traveled, to places of near utter stillness and near perfect silence. And even beyond death they went, beyond the skies: to the end of the stars, where the sky gives way to unbroken night, where the only sound, the only motion, was the beating of one pair of wings. Through these, and other horrors the sparrowflies do not name, Light-of-the-Sun sought out Brightest-Star; and at long last, after many years, they were reunited; and out of darkness and death each led the other, until they came again to the skies of home. It is both a reverent and a joyful tale; their most ecstatic dances are in memory of the joy of that coming-home, of the dawn that saw death defeated, at least for a little while."

--Second navigator of the courier vessel Renegade, as overheard in Tamoshar Port

Endeavor x G. Neutral Reader x Hawks

Requested by: Anonymous

Rating: T+; Language and Sexual References/Innuendos

Word Length: 2072

Title: Villains... Or you two?

           “Of course, sir, I’ll head straight over there.” I hang up, putting my phone in my pocket as I leave the coffee shop.

           So, the flame head finally had an epiphany, I think to myself. These past few weeks have been, strenuous, to say the least. Working with heroes guaranteed an interesting time, and I welcomed getting to know some of them personally.

           Not this time.

           I was paired with two of the top three heroes here in Musutafu, and I still cannot decide who got on my nerves more. Was it Endeavor and his blinding ambition? Or perhaps Hawks with his cringe-inducing arrogance? To be fair, I could look past such… qualities, if not for one particular reason that has made me regret becoming a Private Investigator.

           The two heroes flirted with me, unabashedly, ever since they requested to work with me on a cold case that was re-opened after 23 years. Quite obviously, this has led to numerous issues.

           One- We are on a case and must be professional. Which they regularly ‘forget’.

           Two- I have a decade on Hawks, and the gap was even larger between Endeavor and me.

           Three- They were willing to share me.

           Four- I am quirkless, and I did not become the best PI in the world just to be catered by these two.

           Five- That’s about it, but I wanted to hit a nice number to end on. So…

           Getting in my car, I make no effort to speed to the meeting location where Endeavor would share his findings with myself, Hawks, and the small police squad I was given charge of by the Chief of Police; who happens to be a good friend.

           Now, it may appear that I am indifferent about this case, but truth be told, I had solved it days ago. However, my ‘partners’ were reluctant to let me investigate on my own and had convinced the chief to ‘give us time to consolidate the evidence and prepare for a raid.’

           Apparently, the threat was ‘too great a risk’ for Japan’s best PI to take on alone; despite having crossed paths with the League of Villains multiple times during other investigations, arresting several of its members and still completing the task I was hired to do. All while being quirkless, those love-struck fools.

           Nevertheless, I listened to my superiors, ready to save their asses when the time inevitably comes for a confrontation… that they use for showboating.

           Arriving at a warehouse that was a secret meeting place for law enforcement, I stroll through the metal door, greeting a few colleagues as I made my way to the front of the group. With a stern look, I urge Endeavor to share his ‘findings’, ignoring Hawks’ flirting. Neither hero was perturbed by my blatant disregard for their advances, and Hawks was content with looking up into my eyes (being several inches taller than normal had its advantages; this was not one of them) as Endeavor spoke in his usual proud tone.

           “After much consideration and deliberation, we have deduced the location of the criminal organization that has been feeding vital intel to the League of Villains. After this brief, we will suit up and take action. Now…”

           Having lost interest in his droning, and not wanting to listen to Hawks comments, I let my mind wander on the multiple high-profile villains that were associated with this case. Over two decades ago, these few villains had banded together and wreaked havoc in northern Europe. After being discovered, they scattered, establishing small safehouses for information gathering, always in touch.

           I had been working on the case for nearly a year since learning of it, traveling everywhere, calling in favors. I had soon discovered that many of the safehouses had been sabotaged by an anonymous source, which I traced back to my home city in Japan; where the same villains had gathered once more to join forces with the League.

           They were, indeed, not be underestimated, having sold out several allies for personal benefit. Even after 23 years, there was little doubt that age would be a factor in the coming battle; after all, if they could handle an entire nation’s efforts at stopping them, they could certainly hold their own with a small task force. If that task force didn’t consist of specially trained officers, two pro heroes, and the best damn PI in the world.

           “You all know your roles, we leave in 15.”

           Endeavor had finished detailing the mission, and I took the opportunity to head to my car to suit up, having acquired numerous ‘resources’ over the years; many of which were standard issue, but specially fitted and adapted to me alone. It was for the best, as my fighting style sort of required me to stay adaptable, which helped when facing down those with quirks.

           My quiet time didn’t last, unfortunately, as it dawned on me that I was to ride with Endeavor and Hawks… Silently cursing myself for not having my motorbike, as that would mean the two would have to share the sidecar, which would be a hilarious sight-gag, I got into the driver seat and awaited their arrival.

           With a few minutes to spare, I put on a playlist I made to help me relax, while simultaneously pumping me up for a fight. Admittedly, a lot of it was from an animated show I adore; you know, ‘It’s also a gun!’

           While listening to the music, my mind began to wander, and I hesitantly entertained the idea of possibly allowing a single date with the two heroes. If we weren’t trying to save the city, and they at least tried to stay professional, then maybe after all was said and done, I’d go out with them. But, no. Worse was the fact that both were incredibly handsome, and Endeavor was a role-model for me when I was making a name for myself. And I may have a thing for younger guys…

           A heavy sigh escaped my lips when the heroes entered my car, signaling it was time for the raid. 

           “I’m impressed, it only took all seven of you to get me tied to this chair and hang it from the ceiling.” I say smugly.

           I was, obviously, tied to a chair dangling from the ceiling, the seven villains in a semicircle around me while my partners and squad were in the front room, fighting the countless lackeys they hired over the years. Thankfully, I got away from that pointless scuffle and was able to corner the villains we had been searching for. Naturally, they thought they had the upper-hand.

           Oh, were they wrong.

           Best part? The idiots started monologing. They took turns revealing all they had done, like they fucking rehearsed it. I was loving every second of it, considering they were holding my faux ear piece, which functioned as a recorder. They also removed my utility belt, claiming a toy gun and plastic knives. What they didn’t take was my bulletproof vest that was fitted to my body, so it looked natural; nearly a dozen real knives hidden on my person, including the one currently slicing away at my restraints; several shock-absorbing braces on my arms and legs that were reminiscent of an African hero’s panther suit; and a pair of faux glasses that I was wearing with thermal, night, infrared, and UV vision.

           Being kind enough to wait until the end of the monologue, I stayed in the chair, reclining with my legs crossed while snacking on a bagel I had tucked away, a knife twirling in my free hand. When they finally stopped, a string of threats was thrown towards me before one realized my bonds were broken.

           Having spent the 15 minutes they monologued mentally reviewing the info I gathered on them, creating a feasible plan to execute that would incapacitate the three villainesses and the three villains. Then, I was going to interrogate the behemoth of a person that was in charge to find out what secrets they had given to the League.

           The villainesses consisted of one who could electrically charge their muscles for extra strength and speed, one who could bend light to create barriers and turn invisible, and another who could sap the heat from objects to effectively freeze them. The villains, on the other hand, had one who could exhale hurricane force winds, one who resembled a scorpion with a tail and pincers, and another who could increase gravity in a small area. As for the behemoth, they could block out all pain, and had a one time use of a mutated quirk that allowed to double the pain experienced and force it onto someone else.

           Swinging from the chair and breaking the chain holding it, I spun it around as I descended, crashing it into the leader so I could focus on the other six. Hitting the ground rolling, my braces already storing energy, I blocked several charged punches from a villainess before judo flipping her into the tempest breather with the help of the braces, causing him to blow back the gravity shifter and knock him out while he, himself, got electrocuted. The villainess was knocked out from the force of the impact.

           Three down, three to go. Then, the main boss … I may play too many videogames in my spare time. Ah, well. I was having fun, but it got exponentially more exciting when I was charged by the heat sapper and scorpion man; or so they attempted to fool me with. My special glasses allowed me to see the light bender who was shadowing the heat sapper (I probably should’ve learned their names).

           All I had to due was time their movements, so they struck each other, which proved a challenge to me. After all, I needed the scorpion to strike and poison the heat sapper who would, in turn, flail and steal the heat of the light bender, freezing them in place.

           Or, I could go a route that relied on actual skill, and not arbitrary luck (although, there was a heroine back in the states who could manipulate luck; I think she was part of some sort of force with an ‘X’ in it?). 

           Dodging the tail thrust of the scorpion, I grabbed his tail and pulled him into an overclocked punch, knocking him out. Then, ducking under the grasp of the sapper, I grapple her, spin around, and suplex her into the light bender, using up the stored energy in my arm braces (and possibly breaking someone’s bone(s)).

           Finally, I moved on to the big one, seeing as they were finally able to pick themselves up from the ground and face me. I had to be careful with this one, seeing how they didn’t feel pain. But, as a favorite red-headed character from a show I like once said…

           ‘I don’t need him to feel pain; I just need him to GO DOWN!’

           They charged me in a fit of rage, swinging an arm at me. I leapt up, allowing my leg braces to absorb the impact as I was launched into a wall. Once again using my braces, I timed my velocity to kick off the wall with maximum force, shooting towards final villain, and with a simple twist and drop kick, they crashed through the building, skidding into the street.

           Strutting out into the main room where my squad and the heroes were preparing to breach the door that now lay splintered, I drunk in the praise of my squad (after an accidental misfire at me, which didn’t faze either them or me since I still wore my vest); having seen me in action before, they had an inkling of what to expect. As for the two males currently gawking at me, unable to respond, I didn’t hesitate to make a remark while still on my adrenaline high.

           “Well?” I ask, my voice laced with authority as my lips donned a smug grin. “The sooner you two finish up the job, the sooner you two can fire your ‘shots’ in me. Or am I too much for the two of you to handle?” I finish with a wink and coy smirk, leaving to my car.

           The last thing I heard was the scrambling of feet and an argument on who would top me first before I shout over my shoulder, “Who said I was letting either of you top?”

red wall.

(Masterlist)

Parting: Gavin Reed x reader.(android)

Summary: You are the new prototype of CyberLife the Rk1000 and Gavin are partner, even you can do anything as android. One day you were taken during an operation to save him.

~~

“Gavin for fuck sake!”Rk1000 screamed while he was running in the abandoned building, he had not been ordered to do it, but he did it anyway because instead of being safe as any normal person ran.

“I can’t leave you!”Gavin screamed walked next to you, he kept shooting with you. A bullet escaped from your sight, and it hit Gavin's chest that he fell to the ground, you were alone the reinforcements would arrive not soon. So you decided to do the most right thing that you could do.

A robot may not injure a human being or, through inaction, allow a human being to come to harm.

“Okay! I give up but leave him alive."you declared leave standing up with your hands raised.

Two man ran to you and after hit you, they dragged you away, while Gavin tried to get up, the last thing he saw was that you were taken away.

“No...Y/N!”he screamed with all his breath before land down on the ground.

After more time from the day you were kidnapped, you woke up in in the middle of a small room with the suffused light, there were two men in front of you, while they were studying one of your biocomponents. You started feeling pain, maybe because you didn’t have enough thirium.

“Oh the bitch was awaken, now can you tell me what you do with this?”one of man asked showed the bio component that they were studying.

“I don’t know.”you lied while Amanda wasn’t wanting to help you, which made it all the more difficult because the device they were holding, helped you to comunicate between the other androids.

When you answered that, they took a wireless transmitter and electric shock transmitters, they tore off the uniform's shirt and applied it on the chest and on the head.

“I will ask you again:«How do it work?»”he asked activating the wireless transmitter, immediately a terrible pain hit you.

You immediately remembered what did you two weeks ago, they tortured you, probably suspected that you started to feel pain; they collected your thirium. When you were in the danger to go into arrest, they quit for two days but then started again they probably wanted to know something or they did it just for fun.

Amanda was disappointed by you, because you gave in to the feelings. This was why she didn’t help you.

"The best prototype of Cyberlife has yielded to silly simulations of feelings."she said two week ago when you reported to the Cyberlife the the developments of the investigations on the various deviant cases.

You refused to answer and they began to be tortured. The pain you felt was too much, unbearable and impossible to ignore.

At a certain point you started to feel seeing with the thermal vision, you saw people approaching.

“Gavin...”you whispered tired, close one of your eye. The men looked at each other until one of the three pointed to the control monitors.

“Deactivate her.”one of man ordered, the men removed all the transmitters and put their hands on your chest at the height of the pump, they started to search the breach when they found it, you started to cry.

“Please..please don’t do it.”you prayed crying, you started to feel fear and afraid of not being able to see Gavin again, all of it made you confused. Because you had never felt this fear, this dark feeling.

Danger shutdown imminent:0:05:40.

“Help...Gavin...Please..”you murmured kept the eyes opened.

Danger shutdown imminent:0:02:40

“Help!! Someone help me!”you screamed out without your last minute that remained.

Your sight system was going to be turned off to keep the thirium and the energy, the last thing you saw was a blurry face.

“Gavin..the pump are over the table...”you murmured smiling to him.

“Okay, don’t die please.”he started to search the pump, more nervous and agitated.

Danger Shutdown imminent:0:00:10

“I found it!”he screamed happy and running to you.

0:00:09

He put it in one shot, but his hands still shook, your systems were not compromised but you needed thirium and a supervision. Slowly opening your eyes, Gavin said nothing but was quite surprised at how your eyes were. You confused him, you kept watching, while you took off the wires that bound you to the chair. Your LED was blue, even if it was bright red before.

“Are you back so soon?”you asked confused while you were walking to him.

He continued to stay quiet without saying anything, but you couldn’t move and a series of codes appeared and formed a wall between you and Gavin.

No..no..no..

“Amanda!”you screamed angry while you were trying to damage the wall.

“What’s wrong Y/N? You know that it will happen, your device are compromised and you became obsolete, so you will be replaced.”she explained walking near Gavin. You hit again the wall and you saw some pieces of wall, you smiled to Amanda.

“No, I won’t let you win. I don’t want to be deactivated! ”you smiling to Amanda and continued to hit the wall.

“Hey tinny can, what’s your model?”said a man not so tall, with a scar on his nose, was accompanied by an old model the Rk900.

“Nice to meet you Detective Gavin Reed, I’m the Rk1000, the new android sent by CyberLife. You can call Y/N.”you presented yourself and smiled to him.

You started to remember the first day that you met him, you hit more determined.

“Hey tinny, can you do any other things when I’m here.”Gavin commented when you licked the evidence in the crime scene.

“This is Red Ice, I think the murder left it in this living room before kill the android.”you explained standing up and looked the body, you were rebuilding the crime’s dynamics and discovered that one of the main bio component was missing.

“The audio processor are missing. Can you help me to find it or are you busy seeing if there's a change on Tinder? Do not worry, Britney will not write to you and Carla is married and you're too young for her.”you asserted while you’re walking to the bedroom.

The first case, it gave you more straight and hit more and more the wall.

“I can’t leave you or lose you.”Gavin begged, you looked to him and noticed that he came close to you.

“Gavin...”you mumbled looking him, you started to cry but you didn’t know why.

-This is sadness-you though feeling the tears went down on your cheeks.

“You can fight them. We can..fight this. Yes we, because I loved you.”he confessed took your right hand.

You started to hit the wall with more straight.

Again

Again

Again

Again.

The wall went down on the last hit, Amanda shook his head in disapproval and disappeared from your sight as well as the wall. You didn’t see anything, anybody except Gavin,you came close to him, so close that you nose touched together.

He smiled at you, while you tried to understand what had happened before, he put his lips on yours, kissing you. After this you kissed him back, but the kiss didn’t last long, because he broke away and smiling, he approached the exit of the room.

“Never..I say never...sacrifice your life for mine. You are...you are superior to me and...and I mustn’t break these Asimov’s Law.”you mumbled hoping that he didn’t hear you, but he did, turned around and walked to you. Immediately he stopped and after looked you and spoke:”You are my equal...”

“...and I love you”he added in the end continued to walked out while he holding your hand.

First Asimov’s law: A robot may not injure a human being or, through inaction, allow a human being to come to harm.

I lived and loved, some might say, in momentous times, looking back, my dreams were full of prisons in our narcotic drifting slumbers, so many dreams of course were full of prisons, mine were without relief in our induced days and our wingless days, my every waking was incarcerated, each square metre of air so toxic with violence the atmospheres were breathless there, the bronchial trees were ligatured with carbons some damage I had expected, but no one expects the violence of glances, of offices, of walkways and train stations, of bathroom mirrors especially, the vicious telephones, the coarseness of daylight, the brusque decisions of air, the casual homicides of dresses what brutal hours, what brutal days, do not say, oh find the good in it, do not say, there was virtue; there was no virtue, not even in me let us begin from there, restraining metals covered my heart, rivulets of some unknown substance transfused my veins at night, especially at night, it is always at night, a wall of concrete enclosed me, it was impossible to open my eyes I lived like this as I said without care, tanks rolled into my life, grenades took root in my uterus, I was sickly each morning, so dearly what to say life went on around me, I laughed, I had drinks, I gathered with friends we grinned our aluminum teeth, we exhaled our venomous breaths, we tried to be calm in the invisible architecture we incubated, like cluster bombs, whole lives waiting, whole stellar regions, discoveries of nebulae, and compassion from the cities the electric rains pierced us, the ceaseless bitter days folded like good linen, the phosphorous streets gave off their harmful lights we bit our fingernails to blue buttons we staggered at the high approach of doorways, plunged repeatedly to our deaths only to be revived by zoos, parades, experiments, exhibits, television sets, oh we wanted to leave, we wanted to leave the aspirated syllables and villages, the skeletal dance floors, the vacant, vacant moons that tortured us, when the jailers went home and the spectators drifted away and the scientists finished their work like a bad dog chained to an empty gas station, for blue blue nights, I got worse and worse, so troubling I would fall dead like a specimen, at the anthropometric spectacles on the Champ de Mars, the Jardin d’Acclimatation the mobile addresses of the autopsy fields, though I could see no roads, I was paid for losing everything, even eyesight I lived in the eternal villages, I lived like a doll, a shaggy doll with a beak, a bell, a red mouth, I thought, this was the way people lived, I lived I had nights of insentient adjectives, shale nights, pebbled nights, stone nights, igneous nights, of these nights, the speechlessness I recall, the right ribs of the lit moon, the left hip of the lit moon, what is your name they asked, I said nothing I heard the conspiratorial water, I heard the only stone, I ate her shoulder, I could not hear myself, you are mistaken I said to no one the chain-link fences glittered like jewellery, expensive jewellery, portable jewellery, I lost verbs, whole, like the hulls of almonds after consideration you will discover, as I, that verbs are a tragedy, a bleeding cliffside, explosions, I’m better off without, with vermillion, candles this bedding, this mercy, this stretcher, this solitary perfectable strangeness, and edge, such cloth this compass of mine, of earth, of mourners of these reasons, of which fairgrounds, of which theories of plurals, of specimens of least and most, and most of expeditions, then travels and wonders then journeys, then photographs and photographs of course the multiplications of which, the enormity of this, and drill-bits and hammers and again handcuffs, and again rope, coarse business but there some investigations, then again the calculations, such hours, such expansions, the mind dizzy with leaps, such handles, of wood, of thought and then science, all science, all murder, melancholic skulls, pliant to each fingertip, these chromatic scales, these calipers the needle in the tongue, the eyes’ eye, so whole diameters, circumferences, locutions, an orgy of measurements, a festival of inches gardens and paraphernalia of measurements, unificatory data, curious data, beautiful and sensuous data, oh yes beautiful now, of attractions and spectacles of other sheer forces, and types in the universe, the necessary exotic measurements, rarest, rarest measuring tapes a sudden unificatory nakedness, bificatory nakedness, of numbers, of violent fantasms at exhibitions again, of walks, of promenades at fairs with products, new widgets, human widgets, with music, oh wonders, the implications then early in this life, like mountains, already pictures and pictures, before pictures, after pictures and cameras their sickness, eye sickness, eye murder, murder sickness, hunger sickness, this serendipity of calculators, of footprints with fossils, their wingspan of all time, at crepuscules’ rare peace time, if only, like water, in daytime, no solace, so, so different from solitude, all solitude, all madness, so furious, so numerous, the head, the markets, the soles of the feet, so burnt, so thin and the taste, so meagre, so light-headed, the cloud flashes, the lightning geometry, the core of reflectivity so vastly, vastly vast the wait now, lumens of aches, such aches, the horizontal and the vertical aches of lightning, its acoustics, loud pianos, percussive yet strings and quartets, multicellular runnels yet and yet, the altitude of the passageway, its precipitation and grand arithmetic, the segments the latitudes of where, where and here, its contours, its eccentric curvatures, so presently, angular and nautical, all presently just fine my lungs, just fine, hypothesis absolutely, but just fine, why lungs, strange theory oh yes and the magnitude of jaundice, trenches, like war, continuous areas and registers, logarithms so unexplainable, rapid scales, high notes besides, anyway so thermal, atmospheric, wondrous aggressions, approximately here, elaborate like radiation and seismic, yes all over the bodies’ symptoms of algebraic floods, tiredness for one, weariness actually, weary with magnetic embryos petals, yes petals of sick balm please, now yes, for my esophagus, analgesics of indigo, of wires, of electric shocks, why eucalyptus leaves of course lemon grass, labernum, please, lion’s claw, remedies of cloves, bitter bark, still birdless though, worldless asthma with blueness, then music, gardens truthfully, truthfully nauseous with tonsured numbers, volumes of fibres, embroidery and hair nets of violence, blue, like machine guns, of course knives, extensions of blueness, all right then wherever same radiations, lines in the forehead, tapers, electrodes, invisible to the eyes, official hammers and corkscrews, official grass official cities now for appearances after all this, all these appearances, generous, for certain scraggly, wan, and robust appearances assignments and hidden schedules of attendance, a promise of blindness, a lover’s clasp of violent syntax and the beginning syllabi of verblessness

Dionne Brand, Ossuary I

Why is a Thermal Device So Expensive?

The revelation of 'infrared beams' dates to the start of the nineteenth century by Sir William Herschel, He closed through tests that there is an undetectable light that can warm articles. In 1963, after 163 years, the main warm camera was created. The warm imager doesn't depend on apparent light yet warm radiation from the item. It changes over it into Thermal Imaging Scope that is apparent to the unaided eye through a progression of sign handling.

It is at first restricted to military applications in light of its grouped use and excessive costs. Around 2000, following quite a while of advancement, warm imaging innovation has step by step developed and is broadly utilized for a considerable length of time. Notwithstanding, the cost of this innovation is still too far for most potential buyers today, and this article covers the reason why that is

While purchasing a warm gadget, we take a gander at the elements and the sticker price of the item and afterward contrast it and others on the lookout. Warm gadgets appear as cameras, riflescopes, optics, and so forth. Assuming you investigate the commercial center, you'll observe that the costs of these gadgets are somewhat high than standard day optics.

Presently, this could come as a shock from the get go, yet how about we investigate what makes these gadgets so expensive. Here are a few factors that conclude the sticker cost of various warm gear

Warm Imaging Detector

Germanium Lens

Field Programmable Gate Array (FPGA)

Warm Algorithm

Others (gathering, climate, tests, and so on.)

Cryogenic Cooler (for cooled warm imagers)

6 Reasons Why Thermal Devices are So Expensive

We should survey the elements referenced above in more detail.

1. Warm Detector

The indicator is essentially made out of a microbolometer and related circuits. It's answerable for getting warm radiation and changing over it into a computerized signal with radiation force data. The microbolometer is a matrix of hotness touchy materials on a comparing network of silicon. Infrared radiation from a particular scope of frequencies strikes heat-touchy materials, for example, vanadium oxide or shapeless silicon and changes its electrical obstruction. This opposition change is estimated and handled into temperatures which can be addressed graphically by related circuits. The microbolometer framework is normally planned and fabricated in three sizes, a 640×480 cluster, a 320×240 exhibit (384×288 nebulous silicon), or a more affordable 160×120 cluster.

The indicators cost a ton due to their weakness to different ecological circumstances, high power utilization, low large scale manufacturing strength, and reconciliation issues. Since the creation of identifiers requires high stage costs, the interest in innovation innovative work is additionally a sizeable consistent venture. The improvement of every boundary implies the redesign of the whole framework. There is still a lot of opportunity to get better in center markers, for example, NETD, pixel pitch, and amplification, which drives producers to proceed to research and move up to guarantee that they won't essentially fall behind their rivals.

2. Germanium Lens

A few top notch warm gadgets use germanium glass focal points. They have a high refractive record, permitting the IR scope of frequencies to go through and arrive at the sensor that recognizes an objective.

Due to the uncommonness of the germanium metal, it costs 1500 dollars for each kg; and that is only the expense in its crude structure. Whenever you add the cost of refining and handling germanium into an elite exhibition long-range warm reconnaissance focal point, the complete expense of the gear increments dramatically

Likewise, it relies upon the opening (the F-number of the gadget); the lower the F-number is, the more costly the focal point costs.

For more details, visit us :

Thermal Polaris 350RL

Thermal Imaging Sights

Thermal Scope for Sale Australia

Thermal Tracer 50 LRF

In order to reduce the cost of decoration, the person in charge of the factory used ordinary power sockets to cause instability of the circuit and heavy casualties!

    The factory always ignores electricity safety in the production process, and no one pays attention to these problems. Until August 9, when the factory was producing electronic products, a fire broke out, killing at least 52 people and injuring nearly 30 people. This time the explosion not only caused heavy losses, but also caused a fire. Shortly after the firefighters put out the fire, three more victims were found. The next day, another 49 bodies were found with heavy casualties.

  The accident had a considerable impact on the local area, not only causing heavy casualties, but also property losses. The local government attaches great importance to it and arranges for local police and professionals to enter the incident site for investigation. After investigation, the reason was that the factory did not pay attention to the use of electricity when producing goods, which caused a short circuit and damaged electronic equipment. It caused a small explosion, ignited the product packaging, and set off a fire

    Later, the government issued a notice telling major manufacturers not only to regularly check whether the circuits in the factory are normal or aging, but also to install plugs with leakage protection on each circuit and take professional protective measures.For example: install a leakage protection plug in the circuit. When the electrical equipment is operating normally, the current in the circuit is in a balanced state, and the leakage switch is closed; when the equipment shell leaks and someone gets an electric shock, the leakage switch will automatically turn off. The buckle cuts off the power supply, ensuring that the current can be cut off within 0.01 seconds when the line is short-circuited, ensuring no leakage and protecting personal safety.

    Our leakage protection plugs are compact, convenient, and wide voltage (100-240V) are also applicable to various countries, such as the United Kingdom, the United States, Japan, India, Hong Kong, China, Taiwan and other places. The same can be used in different places of use, whether it is large-scale processing equipment and electronic equipment in the factory, as small as household air conditioners, refrigerators, vacuum cleaners and other electronic equipment, and can also be used according to different needs. Corresponding plugs and wires And so on, the material is also made of PC material (polycarbonate), a thermoplastic engineering plastic with high mechanical, optical, electrical and thermal properties. This extremely tough, easy-to-process polymer is suitable for a multi-purpose shell made of materials, which can bring further security.

https://www.aliexpress.com/item/1005002822114855.html?spm=5261.ProductManageOnline.0.0.2ad94edfXbqC81

After many years I finally settled on a design for Jerry’s aunt Irene!

Here’s a little bit of behind-the-scenes concept work that went into this one

As often as I explore different hair styles in designs I find I always come back to my first idea, not sure how good or bad that is but it hasn’t failed me yet lmao. Her having vitiligo was always locked in, but I was playing around with an overbite and something just clicked. She’s a singer/songwriter and I didn’t realize until after the fact that Freddie Mercury also had an overbite so I call that a happy accident!

How to prepare a Career Episode Report for Professional Engineers?

Skilled Engineers applying to Engineers Australia must submit three career episode reports as part of their competency demonstration report (CDR) (CERs). Engineers Australia’s Career Episode Report provides extensive information on the technical and other abilities that an engineer utilized for the project mentioned. In your career episodes, you must exhibit your professional abilities. Here is an example of a Career Episode Report for a Professional Engineer.

PART-I INTRODUCTION

Career Episode 1.1

The career episode is based on the project “BUCHI Unit for Protein Analysis.” I completed this assignment while working as an Executive Trainee in the Manufacturing Department. The XXX is the name of the firm where I worked at the time (name and location of company). The project was completed successfully between September of 2014 and December of the same year.

PART-II BACKGROUND

Career Episode 1.2

XXX (Company Name) is a division of XXX (Company Name) with headquarters in XXX (Company’s Location). Both firms operate separately and have separate headquarters; XXX (Company Name) is based in DLF XXX (location), whereas Pharmaceuticals is based in XXX (Location). The XXX location became the mother factory in India, producing Horlicks and its variations for the Indian market. The facility has a capacity of roughly 100,000 metric tons per year. XXX (Company Name) has three distinct manufacturing locations that produce the same product, but XXX (Company Name) outperforms incapacity. Protein calculations are crucial in the food and chemical industries.

The process, however, involves the handling of chemicals such as sulfuric acid and organic liquids, and the previous equipment utilized in the process had heated surfaces and was not shockproof. As a result, it is regarded critical to improving the safety of the analyst and the efficiency of the protein calculation system in terms of energy savings, which is being done in this project.

Career Episode 1.3

The main gist of this project is to improve the BUCHI Unit for Protein Analysis’s efficiency. The following are the project’s particular objectives:

to assess existing system risks and concerns

To increase the analyst’s safety throughout the protein calculating procedure.

to create a new system that meets the criteria while minimizing possible hazards

To set up the new system

To be put into service under the supervision of the safety manager.

Trials will be conducted to evaluate the new system.

to improve the protein calculating system’s efficiency in terms of energy savings

to create an energy usage data analysis report

Career Episode 1.4

Under the direction of Mr X, I completed this project for the organization XXX (Company Name and Location). This project’s organizational structure should be defined in depth.

Career Episode 1.5

The following are the tasks and responsibilities that I fulfilled while working on this project:

The sort of glass to be used must be resistant to acids, alkalis, and organic compounds.

To guarantee that there are no leaks of hazardous acid gases.

To determine the size of the condensation zone to prevent acid splashing.

To work with the process engineer to guarantee a flawless installation.

Examine the new equipment’s design and its compatibility with the product to be examined for protein calculation.

To examine the data in terms of the total time required by existing and new systems.

To assess the system’s efficiency in terms of energy usage.

PART-III PERSONAL ENGINEERING ACTIVITY

Career Episode 1.6

My theoretical knowledge obtained throughout my undergraduate study was converted into practical applications, which are described below:

I utilized my understanding of chemical engineering to calculate the proper amount of sulfuric acid to use that is non-toxic and safe for humans and the environment.

I utilized my expertise in material selection to choose the appropriate ingredients for the culinary product.

I used my mathematical skills to determine the size of the new system such that it took less time to complete one cycle than the prior system.

I used my understanding of the chemical system’s safety PPE requirements to improve the analyst’s safety.

Using my expertise in maintenance engineering, I conducted preventative maintenance on the new system.

Career Episode 1.7

The fumes produced during the protein-digesting process must be kept under control. I researched different publications, papers, and studies on the issue of operator safety throughout procedures. Condensation zones are defined as hot surfaces and regions dangerous to the operator and cannot be entered without adequate verification throughout the operation.

The condensation zones are set to avoid acids from splashing on the operator. The discharge of acid fumes into the air was hazardous, so I researched ways to regulate the fumes and convert them into a less harmful substance or gas that might be used in other applications. I discovered that the vapours could be concentrated and collected in a tank. I researched the pollution control standards that a food and beverage manufacturing firm must follow.

Career Episode 1.8

I chose the materials required to meet the specifications of the new system design. I went with a system with a shock and heat-proofing body. I placed fireclay on the plates of the BUCHI system’s surface to act as insulation. For a fill level sensor, I employed a Hall Effect sensor. A safety sensor is selected that continually checks the system’s temperature and stops heating when the temperature reaches a crucial limit. The specific dosage of sulfuric acid is chosen since this acid is potent, and the protein analysis method necessitates the analyst’s handling of the acid.

This method necessitates the use of chemically resistant, thermally, and shockproof glass. So I went with the Borosilicate glass 3.3, which has all of the essential characteristics. Infrared rays were used as the system’s heating medium.

Career Episode 1.9

In the foremost part of my research, I tackled the difficulties associated with unregulated heating. The previous method included gas burners to heat the glass tubes used in protein calculations. The heating system was manually regulated, resulting in bursting and chemical leakage in some circumstances if not adequately monitored. Because of the unregulated heating system, the analyst may suffer safety concerns in some circumstances.

The new system, known as the BUCHI system, was created by me. It was outfitted with safety sensors that continually monitored the system’s temperature. Infrared rays were used as the heating medium in this case. When the temperature exceeds a certain level, the safety sensor activates, and the heating is turned off. The risk of rupture and chemical leakage is much decreased in this controlled environment.

Career Episode 1.10

Following that, I investigated the hot surface and electric shock issues in the system. The old system was an open system with heated surfaces that might burn you. There was also a significant possibility of electric shocks. It is highly risky for an analyst to handle the glass tubes while working on the system, even with safe handling equipment. I created a novel system with unique stress absorption and a thermally resistant body.

The plates on the surface of the BUCHI system were insulated by inserting a fireclay. I ran the calculations to determine the size of the new system such that it took less time to complete one cycle than the prior system. This covered the size of the tubes and the critical temperature limit at which the heating would halt. I worked out the crucial temperature limit.

Career Episode 1.11

Sulfuric acid was the primary chemical utilized in the protein-digesting process, resulting in acid vapours’ emission. I built the channel for the acid fumes to exit from the system to ensure adequate condensation and use the least amount of space. Then I devised a system that included a suction device linked to all of the tubes coming from their mouths. The suction unit aimed to suck out the hazardous vapours, removing the potential for these vapours to mix with the laboratory air and reduce the risk. On the other hand, the present arrangement had a chimney built on the top of the chamber, but there was a risk that the acid fumes would not leave correctly and might mix with the laboratory air. If the analyst breathed the gases, they would be in danger. As a result, I presented the new approach while keeping these aspects in mind.

Career Episode 1.12

I took into account all of the designs mentioned above procedures before installing the new system. The installation in XXX (Company Name) went off without a hitch. The installation of the BUCHI unit increased the analyst’s safety and the protein calculating system’s efficiency in terms of energy savings. Under the supervision of the safety manager, I also commissioned the new system. Following that, I tested the system’s functionality. I initially test the system on the water to ensure that all of the system’s components are in good working order. After some hits and tries, the testing came out positive. The suction device was checked to see whether there was any fume leakage. The tests were successful, and no vapours were detected in the laboratory air or, as a result, in the surrounding air.

Career Episode 1.13

After the testing was finished, the new system was put into the entire operation. Because the test findings were all positive, the new system was approved for usage. Then, for maximum productivity, I did periodic maintenance on the new system. I was in charge of the daily maintenance, which included turning the system units on and off. I also performed weekly maintenance, which included lubricating the moving parts. I was in charge of the calendar maintenance because the sensors could only be used for 2000–3000 hours.

Career Episode 1.14: Technical difficulties

The glass that was being utilized for the chemical analysis at the time was not resistant to acids, alkalis, or organic compounds. It did not additionally absorb the shocks. This a significant health risk to the analyst. After careful consideration with the lab attendant and the process engineer, I determined that the glass should be chemically resistant, thermally stable, and shockproof. Chemically, Borosilicate glass 3.3 possessed all of the essential characteristics, which DURAN eventually delivered.

The vapours sent into the atmosphere by sulfuric acid and other organic liquids polluted the environment. Even after running it through the sucking tube, it was dangerous to do so since it presented various health risks to people and the wildlife in the area. As a result, I opted to utilize a sulfuric acid condenser, which was then collected in a tank.

Career Episode 1.15

With the help and supervision of my supervisor, I completed my time as an executive trainee. The knowledge I gained from the Safety Manager about the safety requirements for working in such a system assisted me in designing the line and using other safety accessories appropriately. The lab attendants assisted me in analyzing the current system and inform us of the potential hazards they experience in their daily operations. I also collaborated with Mr A, the process engineer, and Mr B, the Quality Analyst, to identify possible hazards in the existing and new systems.

I used to have weekly meetings with the plant manager every Monday after the morning meeting to discuss progress, ongoing concerns, and allocated tasks for the week. Every Tuesday morning, I would meet with my Manager, Mr X, to go over the critical issues. In doing so, I followed the company’s laws and regulations while maintaining my standards and ethics throughout the assignment. Because sulfuric acid vapours are highly toxic, the established limits of the acid are utilized to calculate the acceptable exposure limit, which is 0.1mg/m3 to 3mg/m3 STEL.

PART-IV SUMMARY

Career Episode 1.16

Working on a chemical analysis project has never been easy since we must examine various factors and conditions to complete an activity. The handling of hazardous chemicals and organic liquids is part of a chemical process. Working on this project allowed me to use my academic knowledge in a natural setting. During this assignment, I learned time management and self-discipline. The previous system had safety problems, but the new system checks all safety issues, and the environmental impact is also minimal due to the many accessories utilized to check all CCPs.

The project was well-managed, and the project goals and objectives were met on time. However, the time required for this project was increased by one month to complete all safety inspections. I used my analytical abilities to reach a fair conclusion. The Manufacturing, Quality, and Engineering teams were in charge of the whole project. To attain our objectives, we collaborated as a group. My involvement in the project entailed using the proper materials and equipment to maximize productivity.

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NJIT SCIENTISTS MEASURE THE EVOLVING ENERGY OF A SOLAR FLARE’S EXPLOSIVE FIRST MINUTES Toward the end of 2017, a massive new region of magnetic field erupted on the Sun’s surface next to an existing sunspot. The powerful collision of magnetic energy produced a series of potent solar flares, causing turbulent space weather conditions at Earth. These were the first flares to be captured, in their moment-by-moment progression, by NJIT’s then recently opened Expanded Owens Valley Solar Array (EOVSA) radio telescope. In research published in the journal Science, the solar scientists who recorded those images have pinpointed for the first time ever exactly when and where the explosion released the energy that heated spewing plasma to energies equivalent to 1 billion degrees in temperature. With data collected in the microwave spectrum, they have been able to provide quantitative measurements of the evolving magnetic field strength directly following the flare’s ignition and have tracked its conversion into other energy forms -- kinetic, thermal and superthermal -- that power the flare’s explosive 5-minute trip through the corona. To date, these changes in the corona’s magnetic field during a flare or other large-scale eruption have been quantified only indirectly, from extrapolations, for example, of the magnetic field measured at the photosphere -- the surface layer of the Sun seen in white light. These extrapolations do not permit precise measurements of the dynamic local changes of the magnetic field in the locations and at time scales short enough to characterize the flare’s energy release. “We have been able to pinpoint the most critical location of the magnetic energy release in the corona,” said Gregory Fleishman, a distinguished research professor of physics in NJIT’s Center for Solar-Terrestrial Research and lead author of the paper. “These are the first images that capture the microphysics of a flare -- the detailed chain of processes that occur on small spatial and time scales that enable the energy conversion.” By measuring the decline in magnetic energy, and the simultaneous strength of the electric field in the region, they are able to show that the two concord with the law of energy conservation are thus able to quantify the particle acceleration that powers the solar flare, including the associated eruption and plasma heating. These fundamental processes are the same as those occurring in the most powerful astrophysical sources, including gamma ray bursts, as well as in laboratory experiments of interest to both basic research and the generation of practical fusion energy. With 13 antennas working together, EOVSA takes pictures at hundreds of frequencies in the 1-18 GHz range, including optical, ultraviolet, X-rays and radio wavelengths, within a second. This enhanced ability to peer into the mechanics of flares opens new pathways to investigate the most powerful eruptions in our solar system, which are ignited by the reconnection of magnetic field lines on the Sun’s surface and powered by stored energy in its corona. “Microwave emission is the only mechanism that is sensitive to the coronal magnetic field environment, so the unique, high-cadence EOVSA microwave spectral observations are the key to enabling this discovery of rapid changes in the magnetic field,” noted Dale Gary, a distinguished professor of physics at NJIT, EOVSA’s director and a co-author of the paper. “The measurement is possible because the high-energy electrons traveling in the coronal magnetic field dominantly emit their magnetic-sensitive radiation in the microwave range.” Before EOVSA’s observations, there was no way to see the vast region of space over which high-energy particles are accelerated and then become available for further acceleration by the powerful shock waves driven by the flare eruption, which, if directed at Earth, can destroy spacecraft and endanger astronauts. “The connection of the flare-accelerated particles to those accelerated by shocks is an important piece in our understanding of which events are benign and which pose a serious threat,” Gary said. Just over two years after the expanded array began operating, it is automatically generating microwave images of the Sun and making them available to the scientific community on a day-to-day basis. As solar activity increases over the course of the 11-year solar cycle, they will be used to provide the first daily coronal magnetograms, maps of magnetic field strength 1,500 miles above the Sun’s surface.

Previous experiments

Initially, several design concepts were generated from the data gathered during the "Problem Definition" phase and based on the analysis of literature in the field and the accounts of specialists. These concepts led to a preliminary “Experimentation” phase, where they were explored using 3D printing to ascertain their respective potential to be further refined and used in the later stages of the research.

For the designer-researcher to explore the possibilities offered by the technology, these concepts were split between aesthetic and functional characteristics. This entailed investigating the potential of developing both products (prosthetic parts such as sockets and feet) and processes (experiments with printing methods and printing optimisation). Experiments into 3D printing post-processing were also performed to assess if printed parts could benefit from thermal treatment to improve mechanical performance. Finally, in response to data obtained from the interviews with experts and amputees , the design concepts were reassessed, evaluated and re-organised in relation to participants’ inputs as crucial design criteria. 

Rigid/ Flexible filament printing method

In this 3d printing method, the flexible and rigid materials are mixed to create hinges and joints that are more resilient, flexible and resistant to impact. The use of flexible material in the internal structure of the prosthetic limb also aims to act as a shock absorber.

The parts are designed to be printed "unfolded" on the printer bed and later assembled in an attempt to minimize printing time and post-processing. 

"O"Foot/ Pedal connector

This concept consists in an adapted foot that functions as a regular foot for walking small distances and for support when the user is getting on and off the bike, and that allows the user to connect his prosthesis to the bike pedal, acting as a cycling shoe.

The foot is composed of two parts: the outer part, printed with rigid filament, in a "O" shape. This part was designed to function similarly to a C shaped prosthesis, in which the feet structure stores and returns energy; and the internal part, printed with flexible filament and designed to fit to the bicycle pedal.

The possibility of connecting the prosthetic leg to the pedal allows the user to have a similar power transmission to that of clip-in pedals, without the risk of losing balance when clipping in and off the bicycle.

  Post Processing

The objective of this study is to explore how Annealing, a heat treatment process used to increase the strength and ductility, affects 3d printed parts and can be used to enhance mechanical properties and change 3d printed parts' degree of crystallinity.

The way the filament is extruded during the printing process, heating and cooling quickly, causes the material's internal structure to reorganize itself in large crystals, becoming prone to retain stress and compromising the structural integrity and the strength of the piece. The parts can be annealed to rearrange the polymeric macromolecules to an ordered state.

Without access to the machinery needed to test heat resistance and impact strength, it is not possible to measure how the annealing process, and the change of the crystalline structure of the material, affects the mechanical properties of 3D printed parts. 

However, using an electric oven, the researcher was able to assess how the thermal treatment can deform the parts' shape and if it was possible to minimize the warp effect.

Gasket and their types

GASKET :

In piping, a Gasket is sealing material placed between connecting flanges to create a static seal to maintain the leakage proof sealing in all operating conditions. Different types of gaskets are used to achieve leak-proof sealing between the pipe flange.

A Gasket is an elastomeric component that covers the intersection between two surfaces. They are usually manufactured from a variety of materials, rubber, cork or paper, metal, copper, and foam. This element can be used for a broad scope of purposes due to its functionality. These having anti-vibration, packaging, hygiene, noise and sound reduction, and most importantly, its most common use, sealing.

Industries that use gaskets

A gasket material provides the capacity to resist some of the most difficult environments for industrial sealing products, these include:

Chemical processing

Power generation

Petrochemical and Deep Sea

Oil & Gas

Mining

Military

Aerospace

food processing

pharmaceutical

materials are chosen for their characteristics and capability to withstand a number of environments such as mining and deep-sea, resistance to chemicals, alkaline acids, extreme temperatures, and pressure.

Gaskets are used for?

A leak from the flange joint can be disastrous. A flange leak results in a loss of product and energy. The gasket can help in achieving reliable sealing to prevent the leak from the flange joints.

Temperature – Gasket material must withstand the entire design temperature range of the fluid it handles.

Pressure – Gasket material must withstand the entire design pressure range of the fluid it handles.

Corrosion resistance – Gasket material should not corrode when it comes in contact with the fluid it handles or by the environmental exposure.

Types of fluid – Gasket material should be capable of dealing with different types of fluids if installed in a line that handles more than one type of fluids.

Robustness – The gasket must be capable of withstanding all movement that may occur due to a change in temperature and pressure.

Availability – should be easily

Cost – Cheap and unreliable should not be used at the same time it should not be costly

TYPES OF GASKETS USED IN PIPING

SPIRAL WOUND GASKETS :

This type of gasket is formed by combining metal with softer plastics or synthetic rubber in a winding shape, often reinforced with additional layers of metal without filler. Its unique design yields high thermal and physical stress resistance, coupled with flexibility and resilient sealing. Spiral wound gaskets are often used in piping, pumping, and heat exchange systems. Spiral Wound Gaskets are semi-metallic products intended for high weight and temperature application. This kind of Gaskets can be utilized as a part of all weight from vacuum to the standard 2500 psi flange rating. An assortment of types of the Gaskets is accessible and can be made in an assortment of materials or sizes to suit the prerequisites. The Spiral Wound Gaskets are made out of a metallic ceaseless stripe with an extraordinary moulded profile, combined with a persistent filling stripe (Asbestos, PTFE, Grafoil, Ceramic and so on) equitably twisted in concentric winding under steady stretch. The Spiral Wound Gaskets are fortified on the inward and external diametre by twisting of a few electrically welded winding metal as it were.

FEATURES :

Sturdiness nature

Water resistance

Low maintenance

RING TYPE JOINT (RTJ) GASKETS :

TYPES :

R Type RTJ Gaskets

RX Type RTJ Gaskets

BX Type RTJ Gaskets

SRX and SBX RTJ Gaskets

Specialty RTJ Gaskets

Ring type joint gasket (RTJ Gasket) is a high integrity sealing gasket, high temperature and high-pressure gasket for applications in the petroleum industry, oilfield drilling, pressure vessels joints, pipes and valves

Pipeline Solutions Pvt. Ltd.'s Ring Type Joints Gaskets exceed expectations in high-weight applications, for example, oil and gas investigation and generation. Ring Type Joints Gaskets are additionally utilized on valves and pipework gatherings in refineries and different procedure commercial enterprises. Accessible in both oval and octagonal profiles, standard style R ring sort joints are produced to meet both API 6A and ASME B16.20 sizes and evaluations. Additionally accessible are Style RX Ring Type Joints Gaskets which empowers on get together. This sort is intended to fit the same section as a style R in this way making them exchangeable. For high weights, frequently found in sub-ocean wellhead and Christmas tree frameworks, the style BX is utilized. Subsea adaptations of all styles are accessible with weight equalization gaps. We additionally outline and fabricate uncommon Ring Type Joints Gaskets and bespoke strong metal gaskets for topside and subsea victory preventers. Ring Type Joints Gaskets gaskets can be supplied in an extensive variety of stainless steels, Inconel compounds and other master metals. Coatings accessible incorporate zinc, Xylan and silver. Metallic Ring Type Joints Gaskets are substantial obligation, high-weight gaskets to a great extent utilized as a part of seaward and inland petrochemical applications. They are accuracy built segments intended to be utilized as a part of conjunction with exactness machined flanges. All our Ring Type Joints Gaskets are fabricated by B16.20 and API 6A. • The Ring Type Joints Gaskets material is chosen on various grounds basically; compound similarity with the media and the hardness of the flange. The gasket material preferably should be about 30 Brinell not exactly the flange material to guarantee adequate distortion of the gasket without harming the flange confronting. • Worn, hollowed or eroded flange fixing surfaces can hinder the fixing capacity of Ring Type Joints Gaskets. In such cases, a serrated octagonal RTJ gasket, secured with adaptable graphite or a Maxiflex CR-RJ, can give an interim or crisis arrangement until the flange can be repaired or supplanted. • The fixing surfaces on the Ring Type Joints Gaskets must be easily completed to 63 Microinches and be free of shocking edges, instrument or babble marks. We provide RTJ Gaskets that are precision machined, metallic sealing rings. These gaskets are best suited for high pressure and high-temperature applications. Specially designed to seal by "initial line contact" or wedging action between the mating flange and the gasket, this range is widely appreciated for unmatched performance.

FEATURES :

Rigid

High Efficiency

Durability

Fine Finish

Conclusion :

In this article, I have tried to explain the term gasket in a simple manner. which is easy to understand also explain types of gaskets with their uses and how they work.