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marketingreportz · 5 months ago

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Food & Beverage Position Sensors Market Industry Forecast, 2024–2030

Food & Beverage Position Sensors Market Overview

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Food & Beverage Position Sensors Market Report Coverage

The report: “Food & Beverage Position Sensors Market — Forecast (2024–2030)”, by IndustryARC covers an in-depth analysis of the following segments of the Food & Beverage Position Sensors market.

By Product Type: Contact and Contact-Less By Position Sensor Type: Ultrasonic, Radar Microwave, Tuning Fork, Electromagnetic, Capacitance, Others By Measuring Type: Point Level Measuring and Continuous Level Measuring By Geography: North America (U.S, Canada, Mexico), Europe(Germany, UK, France, Italy, Spain, Russia and Others), APAC(China, Japan India, SK, Aus and Others), South America(Brazil, Argentina and others) and RoW (Middle east and Africa)

Key Takeaways

Rising trends towards automation in food and beverage vertical is anticipated to propel the market growth.

The market expansion of the Food & Beverage Position Sensors Market is expected to be aided by technical improvements in position sensors as a result of the rising demand from the food and beverage sector.

APAC region is dominated the food and beverage position sensor market in 2020. The presence of major F&B manufacturing companies and large number of consumer is going to provide huge growth to F&B flow sensor market.

Food & Beverage Position Sensors Market share in %, by Geography, 2023

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Food & Beverage Position Sensors Market Segment Analysis- By Product Type

This market is segmented into Contact and Contact-Less on the basis of product type. Contact less segment is anticipated to witness a significant amount of growth in the forecast period 2024–2030. The benefits of Contact-less position sensors, such as longer life, reduced wear and tear, unmatched precision, consistent outstanding performance, rapid reaction, and suitability for a variety of settings, are attributed for the market’s rise. Furthermore, non-contact position sensor applications in precise motion control, robotic movement, MEMS accelerometers, vibration monitoring, and other applications help to drive market expansion. The market for Contact-less position sensors is expected to expand due to reasons such as usability in precise measurement, contamination resistance, and high accuracy. Hence, such factors is analyzed to boost the market growth in 2024–2030.

Food & Beverage Position Sensors Market Segment Analysis- By Position Sensor Type

By Distribution channel, Food & Beverage Position Sensors market is segmented into Ultrasonic, Radar Microwave, Tuning Fork, Electromagnetic, Capacitance, Others. Ultrasonic position sensor held the highest market share in 2020. Higher working temperatures and pressures, as well as the presence of steam and potentially corrosive chemicals such as alcohol and solvents, need the use of strong measurement components that can perform reliably under extreme circumstances. Similarly, as machine footprints get smaller, there is a greater demand for sensors that take up less space. All of these aspects have driven the creation of a new line of ultrasonic sensors that will allow producers to achieve optimal performance in a number of food and beverage applications. Ultrasonic sensors have a stainless steel or alumina exterior construction that optimizes performance while adhering to strict food safety requirements. Accurate sensing is critical in applications such as milk metering and beverage distribution to guarantee proper container filling. Ultrasonic metering is a great way to improve accuracy while keeping a small footprint. Thus, above mentioned factors are analyzed to drive the market growth.

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Food & Beverage Position Sensors Market Segment Analysis- By Geography

APAC held the highest market share of 37% in 2020. The rising need for cost-effective and highly efficient position sensors from the food and beverage industries, as well as technical advancements in optical position sensors, are driving expansion in this area. North America region is anticipated to witness a significant amount of growth in the forecast period 2024–2030. Growing spending by key players in the development of position sensors, as well as an increase in the use of position sensors for level measurement in large alcohol tanks, are contributing factors to market growth in this area. Moreover, the growing number of restaurants, fast-food chains, and meal delivery apps such as grub hub, caviar, and others increase customer access, resulting in substantial development in the food and beverage business in this region. Furthermore, growing consumer desire for organic, natural, and fresh foods as a result of increased health consciousness is a significant driver predicted to boost demand for the food and beverage industry. Because of the shift in consumer food consumption trends and inclination toward a healthy lifestyle, the United States is witnessing a strong demand for gluten-free drinks, followed by Canada and Mexico. Consumers in the United States have good opinions of healthful food items, which may drive market expansion. The favorable regulatory environment, attempts by the Food and Drug Administration (FDA) to encourage gluten-free diets, and further subsidy allocations are expected to enhance the regional market throughout the projected period. The major element driving the strategy of Food and Beverage firms is the constantly altering customer trends. Consumers’ lifestyles are changing, and there is a greater demand for processed and ready-to-eat meals, which is fueling the expansion of the food and beverage industry in this area. Thus with the rise of market for food and beverages, the market for position sensors also develops.

Food & Beverage Position Sensors Market Drivers

Increasing focus of manufacturing industry on accurate measurements and detailed inspection are anticipated to drive the market growth

In order to meet industry requirements, the manufacturing business need a high level of precision. To develop high-quality products, manufacturers rely on two critical parameters: measurement precision and thorough inspection. A position sensor detects a number of important properties such as profiling, width, height, step, gap, V-gap, edge, angle, bend, groove, and surface. The profiles on various item surfaces are also detected, measured, and evaluated using these sensors. When the position sensor is linked to the analytics program, many measurement jobs become much easier. As a result, the position sensor is helpful for automating, testing, or monitoring operations where displacement, distance, length, or position characteristics need to be detected.

Rising trends towards industrial automation tends to boost the market growth during the forecast period

Manufacturers in every industry are always under pressure to boost earnings while lowering expenses. Furthermore, the food and beverage sector is under pressure to adhere to FDA and other food safety and quality requirements. Automation is an obvious way to alleviate these constraints, since automated processes have been shown to boost efficiency, improve traceability, and preserve the brand’s reputation while adhering to the necessary laws. According to the World Health Organization, 600 million people worldwide become unwell after eating contaminated food each year, with 4,20,000 deaths, resulting in the loss of 33 million healthy years. As a result, rising concerns about food safety and cleanliness have driven the use of automation in the food and beverage sector to maintain sanitary standards. This in turn drives the market growth for position sensor market.

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Food & Beverage Position Sensors Market Challenges

High cost of ownership restrains the market growth

A position sensor is manufactured using numerous components, such as position magnets, sensing rods, diagnostic light-emitting diodes (LEDs), and connectors, which are supplied by multiple vendors. For instance, the average price of a crankshaft position sensor replacement cost is between $194 and $258, with the labor costs estimated between $104 and $133, while the cost of the parts is generally between $90 and $125. The major challenge for the companies is to increase these manufacturing capabilities, as well as reduce the overall cost of production.

Food & Beverage Position Sensors Market Landscape

Technology launches, acquisitions, Partnerships and R&D activities are key strategies adopted by players in the Food & Beverage Position Sensors market. In 2020, the market of Food & Beverage Position Sensors industry outlook has been fragmented by several companies. Food & Beverage Position Sensors top 10 companies include:

Hauser Management AG

GEMS Sensors Inc

First Sensor AG

ABB Ltd

Siemens AG

Endress

SICK

PCB Piezotronics

IFM

TR Electronics

Turck, among others.

Acquisitions/Technology Launches

In October 2020, sick launched new product for non-contact measurement of speed and length. With the SPEETEC®, SICK is expanding its product range for speed and length measurement of objects moving in a linear path to include technology that measures directly on the material surface. The non-contact sensor is able to measure a wide range of web and continuous materials, as well as blanks with an accuracy of just 4 μm.

Key Market Players:

The Top 5 companies in the Food & Beverage Position Sensors Market are:

GEMS Sensors Inc

ABB Ltd

Endress+Hauser

Baumer

SMD Fluid Controls

For more Automation and Instrumentation Market reports, please click here

#FoodProcessing #BeverageIndustry #FoodAutomation #SmartManufacturing

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midseo · 7 months ago

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Rotary / Linear Vibrator Controller, Rotary / Linear Vibrator Controllers, Manufacturer, Supplier, India

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ptlevelindic85 · 1 year ago

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Point Level indicator

Understanding Point Level Indicators: Applications, Types, and Benefits

In industrial processes where precise measurement and control are paramount, point level indicators play a crucial role. These instruments provide essential information about the level of liquids, solids, or powders in tanks, silos, or vessels. Whether it's monitoring inventory levels, preventing overfilling or emptying, or ensuring efficient operation, point level indicators offer reliable solutions across various industries.

1. What is a Point Level Indicator?

A point level indicator is a device used to detect the presence or absence of material at a specific point within a container. Unlike continuous level sensors, which provide continuous measurement, point level indicators simply indicate whether the material level has reached a predetermined point. This simplicity makes them ideal for applications where precise level control at specific thresholds is required.

2. Types of Point Level Indicators

a. Mechanical Level Switches: These switches use mechanical mechanisms, such as floats, to detect material levels. When the material reaches the designated level, the switch is activated, signaling the presence of material.

b. Capacitance Probes: Capacitance probes utilize changes in capacitance to detect material presence. When the material comes into contact with the probe, it alters the capacitance, triggering a signal.

c. Vibrating Forks: Vibrating fork point level indicators consist of two prongs that vibrate at their natural frequency. When material covers the forks, the vibration frequency changes, indicating material presence.

d. Optical Level Sensors: These sensors use light to detect material presence. When material obstructs the optical beam, the sensor triggers a signal.

e. Conductivity Probes: Conductivity probes measure the electrical conductivity of the material. When the material reaches the probe, completing an electrical circuit, it triggers a signal.

f. Rotary Paddle Switches: Rotary paddle switches employ a rotating paddle that is stopped or impeded when material reaches a certain level, signaling its presence.

3. Applications of Point Level Indicators

a. Inventory Management: Point level indicators are commonly used in inventory management systems to monitor material levels in storage tanks or silos. By providing timely alerts when material levels reach predetermined thresholds, they help prevent stockouts or overfilling.

b. Process Control: In industrial processes, maintaining precise material levels is essential for ensuring optimal operation and product quality. Point level indicators help control material flow, preventing equipment damage or production bottlenecks.

c. Safety Monitoring: Point level indicators play a crucial role in safety systems by detecting high or low material levels that could lead to hazardous conditions, such as spills, leaks, or equipment failures.

d. Pump Protection: In pump systems, point level indicators prevent dry running by signaling when the liquid level is too low, protecting pumps from damage and extending their lifespan.

e. Overfill Prevention: In storage tanks, overfilling can result in environmental hazards, regulatory violations, and costly cleanup efforts. Point level indicators help prevent overfilling by signaling when the tank reaches its maximum capacity.

4. Benefits of Point Level Indicators

a. Reliability: Point level indicators offer reliable performance in detecting material presence or absence, ensuring accurate monitoring and control.

b. Versatility: With various types and configurations available, point level indicators can be adapted to suit different applications and materials, from liquids to solids.

c. Cost-Effectiveness: Compared to continuous level sensors, point level indicators are often more cost-effective, making them an economical choice for many industrial applications.

d. Easy Installation and Maintenance: Most point level indicators are straightforward to install and require minimal maintenance, reducing downtime and operational costs.

e. Safety: By providing timely alerts and preventing overfilling or emptying, point level indicators contribute to a safer working environment and help mitigate risks associated with material handling. Point level indicators are indispensable tools in industries where precise level measurement and control are essential. From inventory management to process control and safety monitoring, these devices offer reliable solutions for a wide range of applications. With their versatility, reliability, and cost-effectiveness, point level indicators continue to play a vital role in optimizing operations, enhancing safety, and ensuring efficient resource management across industries. As technology advances, we can expect further innovations in point level indicator design and functionality, continuing to meet the evolving needs of modern industrial processes.

#Point Level indicator

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valdomarx · 4 years ago

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Saving Grace

When the test flight of a new experimental spacecraft goes wrong, Sheppard ends up lost in hyperspace. Injured and alone, his subconscious mind summons up a familiar face to keep him company.

Stargate: Atlantis, Sheppard/McKay. 6k words, rated T.

Contains Shep whump, happy ending, and gratuitous descriptions of astronomical phenomena.

Sheppard comes to with a lancing headache and vise around his chest. An alarm is blaring. He takes in his environment: he’s in an unfamiliar cockpit. Whatever he’s flying, the inertial dampeners have cut out and he’s pulling several Gs, the forces pushing him against his seat and making his head swim.

He blinks woozy eyes and stares out the window. Streaks of color whip past him in a confusing and rapid swirl. A strange thrum vibrates the ship. This doesn’t look like space.

Shit. That’s because he’s not in space. He’s in hyperspace.

This is not good.

“It’ll be a cakewalk!” McKay gestures animatedly. “A quick trip across the solar system to warm our new baby up, then kick in the hyperdrive. It’ll catapult you to the Triian system, and you can turn around and gate back. Easy.”

“Catapult?” Sheppard raises an eyebrow. “I don’t love the sound of that.”

But McKay isn’t listening. He and Zelenka are deep in conversation about hyperspace and its effects on the particle/wave duality of light. The rapidly rising volume of their voices suggests this is an argument they’ve had before.

They’re both fussing over the control panel for their latest pride and joy, a cobbled-together prototype spacecraft which is a hybrid between a puddle jumper and a X-302 fighter. It’s taken them months to build the A-305, based off the miniature hyperdrive McKay designed while he was temporarily almost-ascended. They’ve poked and tweaked and run every simulation they can think of, but sooner or later the ship will need to be taken on a real test flight.

Just as well Atlantis has the galaxy’s best fighter pilot for a military commander, Wier had said with a smile. She’d wished him luck on the A-305’s maiden voyage and told him to come home safe.

Stay safe. Stay alive.

Right.

Through the fog in his head, Sheppard focuses on his first problem. The spinning of the ship is making it impossible to think, and he needs to be clear headed to find his way out of this. He needs control of his ship.

With a wince he connects to the ship’s neural interface. It isn’t as seamless as operating a puddle jumper, but the principle is the same. McKay and Zelenka had done their best to replicate the Ancient interface, but their best approximation was still a long way off. Using it adds to the sharp spike of pain in his skull, but he needs to know what he’s dealing with.

The ship’s interface blinks into existence behind his eyes. The sensors scream out incomprehensible reams of data. He silences them. The alarm is still blaring. Silence that as well.

Now. Here. Positioning and guidance systems. This data is a jumbled mess too, and most of the navigation functions are offline. But thrusters are up. That’s good. He can at least stop this spin.

In the corner of his mind, the power system whines needily. It’s one of a dozen systems competing for his attention and it will have to wait. He pushes it aside.

Thrusters. Fire them, hard. Counteract the spin.

The ship jerks and he is slammed into the side of his seat. It pushes the air from his lungs, but gradually the colors outside the window slow their nausea-inducing swirl.

The world rights itself. The G forces release their iron-tight grip on his chest. The ship is stationary.

Now, at least, he can think and he can breathe. He can call for a rescue.

He taps his radio and calls out to Atlantis. No reply. He tries the ship’s communication system. No luck there either. The radio plays back nothing but static.

Ok. Communications are down. He’ll need to fix that, but first he needs to find out where he is. He opens the hyperspace location system and searches for a beacon.

Silence stares back at him.

He searches further, pushing the sensors to their maximum. There must be a signal he can lock onto somewhere.

He finds nothing. Not even empty space. Nothing but the strange, pulsating colors of the uncharted depths of hyperspace.

Damn it. He’s lost.

“I’m telling you,” McKay is, once again, waving his hands around with great enthusiasm, “you have no idea how hyperspace works. It’s not like navigating through normal space.”

Sheppard is sat in the commissary on the Daedalus, overhearing Ronon wind up McKay and trying not to show his amusement.

“I thought it was like an ocean current?” Ronon asks innocently.

“What? No! It’s nothing like that.” McKay gestures with a fork. “It’s more like… You know when you carry something heavy through the forest?”

“Like a body?”

“God, how does your mind work? But right, sure, you’re dragging the lifeless corpse of your defeated enemy through the forest. And as you go, you’re crushing bushes and leaves beneath your feet, right? You’re making a trail.”

“I don’t leave tracks.”

“Oh, sure, Mr I’m-a-big-tough-guy-yet-somehow-I-can-move-silently-through-dense-foliage.” McKay scowls and Sheppard hides a smile behind a forkful of mashed potatoes. “The point is, when a ship moves through hyperspace it leaves behind a trail. When another ship follows the first, it reinforces the trail. Over time, that builds up a network of paths through hyperspace.”

“And that’s how we know which direction to go in right now?” Ronan looks out the window, where the hyperspace currents wrap around the ship.

“Exactly. Over time, we’ve laid out beacons along these paths. They allow us to jump from one part of the galaxy to another, but only along the predetermined routes. If we were to head away from the path, eventually we’d be too far away from the beacons to orient ourselves. We’d end up lost forever in hyperspace.” He shudders, and Sheppard can see the millions of horrible scenarios playing through his head.

“Huh.” Ronon puts his feet up on the table. “If I get lost in the forest, I orient myself by the sun.”

“Unfortunately for your rustic wisdom, that’s not very helpful when you’re outside the normal planes of space and time.”

Ronon gets a glint in his eye and goes in for the kill. “But aren’t there lots of stars out there? And the sun on Atlantis rises in the east, right? So you could pick a star, and head toward it, and that way would be east.”

McKay turns a worrying shade of purple. He gapes. “That is just. On so many levels, that is so unbelievably wrong, I can’t even fathom how you would -” He takes a huge gulp of air. “THAT IS NOT HOW ANY OF THIS WORKS.”

Sheppard does not panic. He reminds himself that the first thing to do when you’re lost is to retrace your steps. How did he end up here?

He remembers prepping the A-305 for the test flight. He remembers heading away from Atlantis and deeper into the solar system. He remembers firing up the hyperspace drive.

He remembers the drive spinning up. He remembers a whirring noise. He remembers the pop as the ship made the hyperspace jump.

And then… There had been a spark. A crackle of electricity, here in the cockpit. A bolt of lightning had shot out from one of the rear hatches and struck the control panel.

There had been a terrible screeching sound, and a series of bangs as various components fried out and died. Then a bang louder than the others that sent him reeling. That must have been the drive pod blowing.

He remembers the force of the explosion smacking his head on the console. Then only blackness.

Gingerly, he touches his forehead. His fingers come away wet with blood.

That explains the headache.

He needs to figure out where he is but the data coming from the sensors doesn’t make any sense. He opens the interface again and looks through data on the craft’s position, speed, structural integrity. Anything that could orient him in the nothingness.

The reams of data start to blur together. His eyes are drooping and it’s getting hard to focus. He forces himself to look at each number in turn, but he can’t make heads or tails of any of it. The chilling ache of helplessness starts to crawl up his spine.

“Why don’t you let me take a look at that?”

Sheppard whips his head round. Perched on the edge of the console, flicking through a tablet, is McKay.

He rubs his eyes, but McKay is still there. He didn’t think he was this far gone.

“You’re not really here,” he gasps. Maintaining some grip on what is real and what is not has never been more vital.

McKay tilts his head and smirks, and it’s such a familiar movement that it makes something in Sheppard’s chest loosen. “Of course I’m not here. I’m light-years away in Atlantis, worrying about you.”

“Then what-?”

“You’re lost. Your ship is damaged. You’re alone. And you have a pretty severe concussion.” McKay ticks off items on his fingers. “Your subconscious figured you could use some help. So it called me.”

Sheppard blinks. “You're imaginary?”

McKay shrugs. “I’m a creation of your mind. You knew you needed help, so you summoned up the one person you knew could get you out of this.”

“And that’s you, is it?”

McKay radiates smugness. “It’s ok, Sheppard. You can admit that I am not only the smartest person you know, but also the most inventive. And, frankly, the most handsome as well.” He flicks his hair back in an affected manner. It's awkward as hell.

Sheppard rubs his aching temples. “Lucky me."

He'd known McKay was going to be a pain in his ass since the day they met.

He'd spent three years in Antarctica. It was nice there. Quiet. No one to get in his business or hold him to any obligations.

And then he'd come to Atlantis, and everything had changed.

Now he has a team to protect and more responsibility than any person should have to deal with. Teyla and Ronon, Weir and Lorne, even Beckett, they have all become indelible fixtures in his life.

And then there's McKay. Brash, arrogant, and perhaps the only person in the expedition who has worse people skills than he does. McKay, whose endless chattering and whining has become the cosmic background radiation of his life. He's gotten so used to it that being without it feels like he's missing a part of himself.

“What we need is a reference point to lock onto.” McKay is pacing, as much as is possible, around the tiny cockpit. He’s making Sheppard nervous.

“There’s nothing out there. I've tried to pick up a beacon signal, but it’s no use this far from the hyperspace lanes. The more time passes, the further I drift.”

“Ah ah ah.” McKay snaps his fingers. “So we can’t find a beacon. But maybe we can find something else to use as a marker. We just need a point in normal space to orient ourselves around.”

“But we’re cut off from normal space.”

McKay shakes his head. “Not completely. Hyperspace is orthogonal to normal space, not entirely separate from it.”

Sheppard has only the loosest idea what that means.

“So you should be able to…” McKay starts futzing around with his tablet again. He can’t actually be doing anything, because he isn’t real and neither is the tablet, but his mind apparently can’t conceive of McKay without having him poking at some piece of electronic equipment. “Try the radar.”

“The radar? But radio waves don’t carry through hyperspace.”

McKay beams. “They do if the source is strong enough.”

“But that’s -”

“Are you seriously arguing with yourself right now? You know I’m right! On some subconscious level, you clearly realize that this makes sense. So do you want to bicker, or do you want to get out of here?”

“Fine! Jeez. I’ll try the radar, but it’s not going to work.”

McKay raises an eyebrow, like he’s about to say wanna bet? Sheppard clamps the headphones over his ears.

Using the neural interface, the radar signal comes through as auditory information. He hears the rumbling of the radiation coming from his spacecraft, and the pings of neutrinos twisting past at super high velocities. So far so unhelpful.

And then… there’s something… And then it’s gone again. Sheppard strains his ears, reaching out with his mind to extend the range of the radar. There’s nothing, only horrible blankness. And then - there it is again.

A faint, very low pulse. Beating like a heart, every second. Thump. Thump. Thump. Thump. Thump. Steady. Consistent. A fixed point.

Sheppard lets out a breath. He’s found a pulsar.

He’d barely been paying attention when McKay had brought it up. He’d been more interested in flicking through the dog-eared copy of Golfer’s Digest he’d borrowed from Lorne.

“See! Right here! Pulsar J0056-87.” McKay gestures him over, vibrating with excitement.

Sheppard rolls his eyes but stands all the same. McKay’s been on at him to join him for a night of stargazing since he found an Ancient telescope stashed away in a lab somewhere. Apparently, even with their elaborate technology, there were still some Ancients who enjoyed looking at the stars with glass lenses for some reason. Bunch of damn hipsters.

But the night was warm and clear, and for once there was no imminent threat of invasion. McKay had dragged him along to one of the distant piers and set up while Sheppard had busied himself with a beer and a magazine.

“Look!” He lets McKay manhandle him into position in front of the telescope eyepiece. “See that?”

He peers through the glass and sees a blurry outline of something like a star. But it flashes, on and off, on and off, like a strobe light.

“It’s the collapsed core of a massive star,” McKay says, all expressive gestures, “and it's spinning so fast it's emitting beams of electromagnetic radiation from its poles as it turns, like a lighthouse. That’s why it seems to flash, and that means it can be used like a yardstick for the galaxy. It’s the only one we’ve found in Pegasus.”

Sheppard grunts, says, “Thrilling,” and goes back to his beer.

“We’re going to get you out of here, Sheppard.” McKay sounds confident, but McKay always sounds confident. Sheppard has learned to temper his expectations.

“Ok. I've located the pulsar. Can we use its location to extrapolate the coordinates for Atlantis?”

McKay pulls a face. “That would require triangulation - we’d need at least three fixed points for that. We’ve only got one point to work from.”

“So how does that help? We’re still lost.�� A churning mixture of anger and anxiety rolls in his chest.

“You have to head toward the pulsar.” McKay nods decisively.

“Oh, what a great idea, I’m so glad I have you here for inspiration. I’m lost in hyperspace, so let’s go even further out. Let’s go deeper into the unknown. Let’s throw all of my eggs into this one strobing basket. Brilliant plan, McKay!”

“And what’s the alternative? Sit here and wait to die?”

“Protocol states that I should stay where I am. Preserve my position. Give a rescue team the best chance to find me.”

“And that’s all well and good in normal space, but we’re not in normal space, are we? There’s no maps here. There’s no way for a ship to track us. They can’t rescue you if they can’t find you.” Sheppard glares at him. McKay pouts back. “Since when have you given a shit about protocol anyway?”

Sheppard grimaces and checks the thrusters. He can at least see how much fuel he’s got left.

He reaches into the interface with his mind.

FUEL DEPLETED, a warning flashes. REFUEL IMMEDIATELY.

“Ahh.” McKay looks apologetic. “I was worried about that. I guess when the hyperdrive blew it took the fuel containment with it.”

Sheppard stares out at the rippling nothingness.

Great.

Sheppard has faced death many times.

There was a time when he would have been fine with this. Going out in the line of duty, he figured that was more or less inevitable given the choices he makes.

But things are different now. There are people counting on him. There are people who care about him.

There are people he cares about too. He doesn't know exactly when they became so important to him. But how does know he doesn't want to die without seeing them again.

He considers his options. He doesn’t have many.

“If I follow the pulsar, I’ll drop out of hyperspace halfway across the galaxy.”

McKay looks at him like he’s stupid. “Yes. That’s rather the point.”

“But the team will be mounting a rescue. I need to stay near to where they left me.”

“That won’t work!” McKay waves his arms in the air. “Even if they find a way to enter hyperspace at exactly the same point you did, and even if they could recreate the accident that sent you here, we’ve still drifted too far to be in communications range. They’ll never find us.”

“What’s your suggestion then? Throw myself at the nearest shiny thing and hope it magically leads me home?”

McKay stops his pacing and kneels in front of Sheppard. He takes his hand. It’s weirdly warm.

“What do you think I’m doing right now? Back on Atlantis?”

Sheppard shifts in his seat and takes his hand back. “I’m sure you’re trying to find me.”

“Ya think?” McKay goes quiet, and that’s so unexpected it rattles Sheppard more than the threat of imminent death.

“This is my fault,” McKay says, standing and turning away. “The jumper hyperdrive was my creation. It’s my fault it failed, and it’s my fault you’re lost.”

“I don’t believe that.” Sheppard waves a dismissive hand. “I’m a test pilot. It’s literally my job to fly experimental vehicles. There’s always a risk. I know that, and if you’re part of me then you know that too.”

McKay turns to give him a sad half-smile. “Yeah. I know you think that. But you also know me - the real me - well enough to know that I’m never going to forgive myself if we lose you.”

That hits a little too close to home. He shoves down the swell of emotion closing up his throat and tries for flippant. “So what? I don’t want you to feel bad, and I don’t want to die here. But pointing my ship to a point in space and hoping you’ll know to find me there? How’s that supposed to work?”

“I know how you think, Sheppard. I know how hyperspace works. I know that your ship has been damaged and that you’re lost. I also know you’ll be able to locate the pulsar. And I know you’ll head toward it. I’ll be waiting for you there.”

“It was months ago that you told me about that pulsar. And I was barely even listening to you at the time! How do you know you’ll remember?”

McKay fixes him with a steady gaze. “I’ll remember.”

Here’s what really happened: McKay invites him to the pier for stargazing. The night is so clear that the stars of Pegasus blanket the sky. The air smells of salt from the sea and the crackling of ozone from the shield generators.

Sheppard pretends to flick through his magazine as he watches McKay set up the telescope. He watches the way his hands dance over components. He listens to him mumbling to himself about which piece goes where.

And then the telescope is ready, and McKay begins searching the sky. Sheppard watches his face as he scrunches up his eyes to focus on the eyepiece. He pretends to drink his beer and he observes.

He’s beautiful like this, Sheppard thinks. Give McKay a puzzle, or a mystery, or an unknown, and he simply expands his mind to meet it. Once he’s solved the problem, then he’ll snap back into his defensive egotistical genius mode. But in the moment just before that - when he sees the solution in front of him, when a new piece of understanding begins to take shape - then McKay glows.

“Ohh,” McKay breathes, face still hovering over the telescope. “Would you look at that. A pulsar, right here in Pegasus.”

Sheppard takes a swig of beer and pretends not to be interested.

It’s one of his favorite memories of Atlantis.

“Even if I wanted to follow your crazy plan,” Sheppard begins.

“Your crazy plan, technically,” McKay interrupts. He gestures to himself. “Figment of your imagination, remember?”

“Even if I wanted to follow this crazy plan, then. Thrusters are out because I used the last of the fuel to stop the spin. The hyperdrive is fried. How am I supposed to maneuver anywhere?”

McKay raises an eyebrow and taps meaningfully on the oxygen gauge. “I’m sure you’ll think of something.”

“The life support? Oh yes, that’s brilliant. Let’s vent the last of my oxygen into space. I always wanted to try death by hypoxia.”

“Venting gases from the ship will create thrust,” McKay says, and he truly must be a fantasy because the real McKay never speaks with such patience. “We don’t need much. Just enough to overcome inertia and start us moving in the right direction. No friction in hyperspace.”

“Even if I vented half the oxygen and got moving, I’d still need to jump out of hyperspace.”

“Oh no no no no no no,” McKay wags his finger, and that’s more familiar. “With the drive in the state it’s in, we will not be jumping out of hyperspace. We will be falling out of hyperspace, like a stone through a pond.”

“That doesn’t sound great.”

“It’s not! But it’s your only option, so hop to.”

Sheppard scowls. “How am I supposed to fix the hyperdrive? You’ve been working on it for months, and you barely got it functioning.”

McKay gives him a look. “You’ve spent years looking over my shoulder. You know how to bypass secondary systems and reroute power to the drive.”

“I do?”

“You do.”

Sheppard finds a spanner tucked under his chair. He grasps it and turns to face the panels full of incomprehensible wiring behind them.

Time to get to work.

McKay and Zelenka are bickering again.

“Your simulations are not only wrong, but reckless as well! You can’t patch primary power cables like that. Unless, of course, you actually intend to blow the prototype up.”

McKay snorts. “Don’t be so timid, Zelenka! The power conduits don’t need to carry that much power long-term. We’re talking a short-term bypass here, not a permanent solution.”

Sheppard focuses on flying the jumper and ignores the voices coming from behind him. He considers closing the bulkhead between the front and rear compartments, but then he’d only have to listen to McKay ranting later.

“A short-term solution which could explode at any moment isn’t viable!”

“Please, it’ll be fine. We only need to avoid patching into the main power distribution node. The hardware for primary and secondary power systems aren’t so different. They’re interchangeable if you’re careful enough.”

“Your desire for glory is outweighing your common sense, McKay.”

“And your petty jealousy is unappealing, Zelenka!”

Sheppard puts on his headphones and tunes out the arguing with the mellow sound of Johnny Cash.

“That’s good.” McKay puts a hand on his shoulder. It feels real. It feels nice. “That should channel all of the remaining power to the hyperdrive, give it enough juice for one last wheeze.”

Sheppard stares at the mass of cabling. He’s been going by instinct: cut here, patch there. He should have learned more about how the puddle jumpers work, and about hyperdrives. But he’s gotten lazy. He’s gotten used to having McKay around for things like this.

“It’ll be fine.” McKay is not known for his generosity regarding the work of others, so Sheppard can only assume he’s done the wiring correctly.

But something is bothering him. “Even if we manage to drop out of hyperspace -”

“When,” McKay corrects, “not if.”

“- And even if you are, somehow, miraculously aware of where I’m heading -”

“I am.”

“How are you going to get there? That pulsar is in the middle of nowhere.”

“Don’t worry.” McKay smiles blithely. “There’s a stargate nearby.”

“How do you know that?”

“Because you know, Sheppard. You’ve seen it.”

It feels like decades ago. It was when they had first arrived in Atlantis and they’d been desperately searching for ZPMs. He sits in the control chair and brings up a map of the galaxy in the vain hope it will show the location of a power source.

The room darkens and lights blink on overhead. From where he sits, he can see the Pegasus galaxy from end to end: stars and black holes, planets and comets, all represented in delicate, dancing lights. He searches for power sources and finds nothing.

But there, in a far corner of one of the galaxy’s spiral arms, is a single light flashing on and off, on and off. He notices it out of the corner of his eye, a flashing oddity. Interesting, but not helpful in their current search.

He puts it out of his mind. But as he does so, he notes a label next to the flashing light. The third planet orbiting that flashing star has a stargate.

“You’ve got quite the memory, Sheppard.” McKay is looking at him… oddly. Softly. It’s unnerving.

“Could have been mensa,” he says, unraveling the tension with a smirk.

Predictably, that sends McKay into a rant. “Oh, you just love to bring that up, huh, your great big IQ to go with your great big guns, and you know what else is sure to be huge -”

The power system chooses that moment to scream back to life with a warning klaxon.

WARNING, it says, POWER LEVELS FALLING. LIFE SUPPORT FAILURE IMMINENT.

Right. Time's up.

“If we’re going to do this, we need to do it now,” McKay says. He chews at his lip nervously.

Watching him, a strange serenity washes over Sheppard. Live or die, right or wrong, he is out of options. Time to make a choice.

He locates the pulsar. He prepares to vent the life support. He opens a seal on the opposite side of the ship, and he releases the airlock safety control.

There’s an explosive rush of gas from the vents, and he's slammed into his seat. He punches the airlock shut switch as quickly as he can, hoping he didn't waste too much air.

“Hey!” McKay whoops. “It’s working!”

The ship is moving, sailing through hyperspace and toward the pulsar. He sighs, and takes a moment. At least now he has a destination. It’s better than floating lost.

Then he looks down at his oxygen supply.

OXYGEN LEVELS AT 10% AND FALLING, the system says. DANGER OF PILOT HYPOXIA.

Huh. He should be worried about that, but it seems so far away. It can’t be that important.

There's a rushing in his ears that sounds the roar of the ocean.

He leans back with a smile.

It's the sound of home.

“Sheppard. Sheppard!”

He comes to again with McKay shaking him.

“Don’t you dare pass out on me now.”

“‘M tired.”

“I know. That’s the oxygen deprivation. But you need to hold on a little bit longer. You need to activate the hyperdrive once we’re close enough to the pulsar.”

“He’s not…” His words are slurring. It’s hard to move his tongue. “They’re not going to find me.”

“Yes they are,” McKay’s voice has an edge to it he hasn’t heard before. “Teyla is going to be calling up every contact she’s ever made. She’ll find someone on the nearest planet, and she’ll get us safe passage. And if she runs into any problems, Ronon is going to intimidate the hell out of the entire system until they help. Beckett is on board a rescue jumper right now preparing his medical kit, ready to treat you as soon as they find you. Wier is going to approve the mission in a heartbeat, even though it sounds insane, because she’d sacrifice all of the jumpers and half the city to save you.”

Sheppard blinks. McKay’s face swims before him.

“And I… Sheppard, you already know this, but I am going to move space and time itself to find you. I’m not going to take no for an answer, and I’ll bend the damn laws of physics themselves if I have to. When you drop out of hyperspace, I’ll be waiting there for you.”

McKay’s voice is further and further away. It sounds nice, what he’s saying, but it’s like it’s carrying on the wind across a great crevasse.

“You’ve saved us all so many times, Sheppard. For once, let us save you.”

He wants to believe that. He wants his team to rescue him. He doesn’t want to die here, alone.

But he isn't thinking straight. This whole plan hinges on McKay remembering a conversation from months ago. It’s madness.

“McKay… Rodney… He doesn’t know,” Sheppard croaks. He’s too tired to feel ashamed of how weak he sounds. “He doesn’t know that I listened to him that night. He doesn’t know that I always listen to him. He doesn’t know that..." he breaks off. "I never told him.”

McKay takes his face in his hands and kisses him. It’s so unexpected that it shocks him awake again, enough to register McKay's lips against his own and his fingers tangling in his hair. It’s like a jolt of lightning, like being raised from the dead.

“I know, John,” McKay says, pulling back and looking him dead in the eye. “I’ve always known.”

He points down at the hyperspace activation button.

“Now come home.”

Sheppard summons the last of his strength to raise his arm. It’s like wading through concrete. One last task, he thinks, and then I can rest.

He presses the button.

There’s a ripping sound, a whirl of lights, and then there’s only blackness.

He wakes up to the familiar surroundings of the infirmary: the bustle of doctors moving around, the distant sound of the ocean.

And frowning down at his laptop, McKay, sitting hunched in a chair by his bed.

The breath Sheppard lets out feels like a great weight lifting from his chest.

"Hey," he says. His voice is raspy and everything hurts. "What happened?"

McKay scrambles to his feet. "Sheppard." His face is guilt-stricken. "Carson!" he calls. "He's awake."

Soon enough, the whole team is crammed into the infirmary.

"We had to search the entire pulsar system to find you," Elizabeth explains. "By the time we got to you, your ship had been without power and oxygen for several minutes. Carson worked very hard to get you breathing again on the trip home. You gave us quite the scare."

That would be why his lungs ached.

"It is good to see you awake, John." Teyla bows her head. "I hope you will join me for tea when you are feeling better."

Ronon snorts. "Or come down to the gym for a sparring session if you want a real challenge. I'll be waiting." He grins.

Elizabeth looks around and smiles. "We're all very glad to have you back." She glances at McKay, huddled quietly in the corner. "Even Rodney. He's been here since we brought you in." She gives him a tight nod and turns to leave, guiding Beckett, Teyla and Ronon with her.

Sheppard looks at McKay expectantly.

McKay pushes his laptop aside. He takes a deep breath and straightens himself up like he's heading into battle.

"I'm sorry, Sheppard." He's not quite meeting his eyes. "I sent you out in that ship, and I told you the drive was ready. It's my fault you were stranded. You must be angry, and I'll understand if you want me off the team."

Sheppard raises an eyebrow. "Did I just hear an actual apology? From you?" He breaks into a grin. "My head injury must be worse than I thought."

"Way to ruin the moment, you ass." McKay leans over to punch him in the shoulder, which hurts, but McKay is smiling now so it's worth it. "I'm trying to bare my soul here."

"Well put it away. I'm not angry, and I don't want you to go anywhere." He looks at McKay's fingers twitching anxiously on the bedspread. In a moment of wild abandon, he takes his hand in his own and gives it a squeeze. "I knew you'd find me."

"Oh. Uhh. Really?" McKay is staring down at their joined hands, but he doesn't let go. The tips of his ears go very pink. "That's very. Uhh. I'm touched by your. Uhh. Your faith in me."

The moment stretches, and Sheppard wonders if he's supposed to say something else. Then McKay fidgets, and the moment passes.

"How did you figure it all out, anyway? I saw the state of the A-305. Getting that wreck out of hyperspace can't have been easy."

Sheppard rests back against the pillow. He feels bathed in warm light. "I had some help," he mumbles as sleep begins to take him, "from a very good friend."

It's a week before Sheppard is well enough to be released from the infirmary. He's still a little shaky, but Beckett says he'll be fit for active duty soon enough.

He makes the most of his new-found freedom and tells McKay to join him on the east pier that night, and to bring the telescope. He trades a month's worth of rations for enough meat for a couple of turkey sandwiches and some beers. He figures he at least owes McKay dinner.

When he arrives, McKay already has the telescope set up. A few lonely clouds drift through the night sky, but the stars overhead glow all the same.The lights of the city twinkle, the spires reaching up into the dark sky.

"Will you find it for me?" he asks.

"Find what?"

“You know what.” He gestures at the stars and gives him a smile, which McKay haltingly returns, and he lays out their dinner as McKay tweaks dials on the telescope. It doesn’t take long.

'Here." McKay waves him over, and he looks through the eyepiece to see it once more: blinking in the night, steady like a heartbeat, constant and true. The pulsar.

Sheppard lets out a breath and something soft uncoils in his chest as he looks at it. "That's our star," he says, moving to sit on the pier with his legs dangling over the edge.

"Our star?" McKay joins him. He sits close by, and he radiates warmth in the cool night air. "You're a romantic at heart."

"I guess I am." He can't resist a grin. "It needs a better name though. 'J0056-87' doesn't have much of a ring to it."

As he sounds out each number, McKay's eyes keep dropping to his lips. He leans closer. So does McKay.

"We could always rename it," McKay suggests. There are only a few scant inches between them, and his voice is low.

Sheppard lets this drag out, a shiver of anticipation running up his back. "Any ideas?"

"We could name it after me." McKay grins too. "I mean, as the foremost astrophysicist in not one but two galaxies, it seems only apt -"

Sheppard interrupts what he's sure would be a lengthy recap of McKay's skills and career by kissing him.

Judging by the way McKay kisses him back like he's been starving for it, hands running through his hair and trying to pull him even closer, that was a good call.

It’s dizzying and overwhelming, and it’s also the most natural thing in the world. When they break apart, McKay’s lips are red and kiss-swollen. It’s a sight Sheppard could get used to.

“I’m really glad you made it back to us,” McKay says, chewing his lip.

Sheppard takes his hand. “I had to make it home,” he says, quietly. It’s like leaping headfirst into an abyss, but knowing that someone is there to catch you at the bottom. “Everything I care about is here.”

#stargate atlantis #mcshep #john sheppard #rodney mckay #my writing #i had so much fun writing this #i am living my most self-indulgent life this 2021

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sapcon-instruments · 6 years ago

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Sapcon instruments provides various vibrating fork level sensors for different purposes.

#level sensor market #sensor #leveling #manufacturer #world

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trumentechnologiesworld-blog · 6 years ago

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Solid, Liquid, and High Level Switch in India at Affordable Price.

Trumen at a Glance

We are an ISO 9001:2015 certified manufacturer & exporter of level sensing, measurement, indication and control instruments. Trumen came into existence in 2009 and initially started with the manufacturing of Tuning Fork Level Switch for liquid and solid applications. With time, the manufacturing range increased with the addition of Capacitance Level Transmitter & Capacitance Level Switch, RF Admittance Level Switches, Rotating Paddle Level Switches, Conductivity Type Solid Level Switch, Vibrating Rod Level Switches, Hydrostatic Level Transmitter, and Radar Level Transmitter & Ultrasonic Liquid Level Switch Transmitter

“To be among the leading solution provider for process sensing, control & automation by working for continuous excellence and innovation in process sensing, measurement, indication and control instruments contributing to dependable process control.”

Solid Level Switch

a) Rotating Paddle Level Switch for Solids

b) Vibrating Fork Point Level Switch for Solids

Electronics of LSV excites the piezo-electric-crystals inside the tuning fork, which makes the fork tines vibrate at their natural resonance frequency in free air.

c) Vibrating Rod Point Level Switch for Solids

Vibrating rod is a single element tunned mechanical element-type Solid Level Switch sensing device. Electronics of LSV-R excites the piezo-electric-crystals inside the tuning rod, which makes the rod vibrate at its natural resonance frequency in free air.

d) Compact Vibrating Fork Point Level Switch for Liquids & Solids

Electronics of LFV11 excites the piezo-electric-crystals inside the tuning fork, which makes the fork tines vibrate at their natural resonance frequency in free air.

Level Switch

a) Admittance Point Level Switch

RF Admittance is a static level sensor with no moving parts. Its sensing parts are:- 1) Earth Extension (body) 2) Compensation Shield 3) Sensing Rod

b) Capacitance Point(s) Level Switch

LMC Capacitance type limit Level Switch is a static level sensor, Sensing parts of LMC capacitance level limit switch is: 1) Earth Extension (metallic process connection may be used as earth in-place of earth extension tubes). 2) Sensing Rod (or Rope as per application).

c) Compact Capacitance Level Switch

LMC30 is a compact capacitance Solid Level Switch limit switch for solids specially intended for see-through plastic window material sensing in packing hoppers. LMC30 can be mounted on any M30 compatible mounting hole and it is supported by two supplied mounting nuts. LMC30 deploys touch sense on its rear, so as to set its switching point and no potentiometer or touch button is presently enhancing the operational life of the device.

d) Top Mounted Magnetic Level Switch MLS20

It operates on the basic buoyancy principle. It uses a float that glides on the surface of liquids. This Level Switch consists of – Terminal Enclosure, Float Stem with Hermetically sealed Reed Switches and Float with magnets assembled inside. As the float rises or falls with a liquid level, the internal magnet moves in or out of the field of the switch resulting in its opening or closing. A non-magnetic barrier tube containing the reed switch isolates it from the process. These type level controls are available for controlling level at up to four different preset locations and can virtually be made of any length. This switch is highly effective and costs shedding and also finds use in a wide range of industries.

Liquid Level Switch

a) Rotating Paddle Level Switch for Solids

Rotating paddle type Level Switch are basically a spring-loaded, eccentrically driven rotating vanes or blades which rotate at a very slow rotation of one revolution per minute, using an ac synchronous motor. The Level Switch LMFS is capable of faithfully detecting industrial fluids and powders using Frequency Sweep technology. Utilizing the resonance of electrical capacitance created by media di-electric and conductivity, LMFS learns the signature of the media to be sensed and thus performs better than other level detection methods for fluids and powders.

b) Conductivity Point(s) Level Switch for conductive liquids

LWS Conductivity Liquid Level Switch is static rendered furnished devices with no moving parts. A low voltage sine-wave is provided into the liquid using a reference rod (or electrode). The electronics continuously scans the sensing rod (or electrode) for the presence of a sine-wave signal on it.

c) Compact Tuning Fork Point Level Switch for Liquids

Electronics of LFV12 excites the piezo-electric-crystals inside the tuning fork, which makes the fork tines vibrate at their natural resonance frequency in free air. When the fork tines are immersed in liquid, the frequency of fork vibration falls due to the density of the liquid.

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pt-equipment · 2 years ago

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Advanced Level Measurement Solutions for Enhanced Process Control and Efficiency

Level Measurement Manufacturer is a critical process in many industries, including chemical processing, oil and gas, food and beverage, and pharmaceuticals. Accurate and reliable level measurement ensures optimal process control and efficiency, as well as safety.

As a leading Level Measurement Manufacturer PT Equipments, offers a wide range of level measurement devices that use the latest technologies to provide highly precise and reliable readings. Our products include radar, ultrasonic, and guided wave radar level transmitters, as well as level switches and controllers.

Radar Level Transmitters

Radar level transmitters use high-frequency radio waves to measure the level of liquids, solids, or gases. They are ideal for applications where the medium being measured has high turbulence, foam, or vapor. Our radar level transmitters are available in two types: pulse radar and frequency modulated continuous wave (FMCW) radar.

Pulse radar level transmitters emit short bursts of radio waves that reflect off the surface of the medium being measured. The time it takes for the signal to return to the sensor is used to calculate the level of the medium. Our pulse radar level transmitters are available in both non-contact and guided wave radar versions.

FMCW radar level transmitters emit a continuous signal that varies in frequency over time. The frequency shift of the reflected signal is used to calculate the level of the medium. FMCW radar level transmitters are ideal for measuring the level of liquids in tanks or vessels.

Ultrasonic Level Transmitters

Ultrasonic level transmitters use sound waves to measure the level of liquids or solids. They are ideal for applications where the medium being measured is relatively calm and free of turbulence. Our ultrasonic level transmitters are available in both contact and non-contact versions.

Contact ultrasonic level transmitters emit sound waves that travel through the medium and reflect off the surface of the material being measured. The time it takes for the signal to return to the sensor is used to calculate the level of the material.

Non-contact ultrasonic level transmitters emit sound waves that travel through the air and reflect off the surface of the material being measured. The time it takes for the signal to return to the sensor is used to calculate the level of the material. Non-contact ultrasonic level transmitters are ideal for measuring the level of liquids in open tanks or vessels.

Guided Wave Radar Level Transmitters

Guided wave radar level transmitters use high-frequency radio waves that travel down a probe and reflect off the surface of the material being measured. The time it takes for the signal to return to the sensor is used to calculate the level of the material. Guided wave radar level transmitters are ideal for applications where the medium being measured has high turbulence or foam.

Level Switches

Level switches are devices that detect the presence or absence of a material at a specific level in a tank or vessel. Our level switches are available in a range of technologies, including vibrating forks, capacitance, and optical sensors.

Vibrating fork level switches use a tuning fork that vibrates at a specific frequency. When the fork comes into contact with the material being measured, the frequency of the vibration changes, and the switch is activated.

Capacitance level switches use an electric field to detect the presence or absence of a material at a specific level. When the material comes into contact with the probe, the capacitance of the electric field changes, and the switch is activated.

Optical level switches use infrared light to detect the presence or absence of a material at a specific level. When the material comes into contact with the sensor, the infrared light is reflected back to the receiver, and the switch is activated.

Level Controllers

Level controllers are devices that maintain a specific level of material in a tank or vessel by controlling the flow of the material into or out of the tank.

Url: https://www.ptequipments.com/products/level-measurement/

Contact +91 98222 74955

#Level Measurement Manufacturer

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hardfacefury · 2 years ago

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Global Vibration Level Switch Market Share, Size 2020 Movements by Key Finding, Revenue and Forecast to 2029

Global Vibration Level Switch Market is expected to reach US$ 932.80 Mn. by 2026, at a CAGR of 6.2% during the forecast period.

Global Vibration Level Switch Market In Healthcare Market Overview:

Global Vibration Level Switch Market In Healthcare The market research report explores and evaluates the market's position during the predicted period. It is in-depth study that focuses on fundamental and secondary drivers, market dominance, key segments, and geographic analysis. The research also looks at notable individuals, large collaborations, mergers, and acquisitions, as well as contemporary innovation and corporate strategy.

Market Scope:

We examined the Global Vibration Level Switch Market In Healthcare Market from every angle conceivable, including both primary and secondary research approaches. This improved our grasp of current market dynamics such as supply-demand imbalances, pricing trends, product preferences, and consumer behavior. Following that, the data is collated and evaluated utilizing a variety of market estimation and data validation procedures. In addition, we have an in-house data forecasting engine that predicts market growth until 2027.

Segmentation:

Vibrating Fork & Vibrating Rod are sub segments of the market for vibration level switches by technology. Liquids and solids are sub segments of the By Application segment. Oil & Gas, Chemicals, Food & Beverages, and Pharmaceuticals make up the By Industry segment.

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Key Players:

Primary and secondary research is used to determine market leaders, while primary and secondary research are used to compute market revenue. The core study included in-depth interviews with key thought leaders and industry specialists such as experienced front-line personnel, CEOs, and marketing professionals. In-depth interviews with important thought leaders and industry specialists, such as experienced front-line personnel, CEOs, and marketing professionals, were conducted as part of primary research, while secondary research included a study of the major manufacturers' annual and financial reports. Secondary sources are utilized to compute percentage splits, market shares, growth rates, and global market breakdowns, which are then compared to historical data. The players highlighted in this report are as follows:

• Endress+Hauser • VEGA Grieshaber • Emerson Electric • KROHNE Messtechnik • Siemens ABB • AMETEK • Magnetrol International • Bürkert Fluid Control Systems • Pepperl+Fuchs • Nivelco Process Control • Finetek Group • Matsushima Measure Tech • Dwyer Instruments • Flowline • WIKA Alexander Wiegand SE & Co. KG • Schneider Electric • OMRON Corporation • Honeywell International Inc. • Baumer • Zimmer Automation GmbH • Gems Sensors, Inc. • CoreAVIThe study provides an in-depth look at the area industry, covering both qualitative and quantitative data. It provides an overview and forecast of the Global Vibration Level Switch Market In Healthcare market by segment. It also provides market size and forecast estimations for five main regions from 2021 to 2027, including North America, Europe, Asia-Pacific, the Middle East & Africa, and South America. The Global Vibration Level Switch Market In Healthcare market in each area is further segmented into regions and segments. The study examines and anticipates several nations, as well as current trends and opportunities in the area.

COVID-19 Impact Analysis on Global Vibration Level Switch Market In Healthcare Market:

We thoroughly researched and analyzed the Global Vibration Level Switch Market In Healthcare Market Development Strategy post-COVID-19, by corporate strategy analysis, landscape, type, application, and leading countries, which encompasses and analyses the Global Vibration Level Switch Market In Healthcare industry's potential, providing statistical data on market dynamics, growth factors, major challenges, PORTER analysis, and market entry strategy analysis, opportunities, and forecasts. The primary goal of the research is to provide enterprises in the industry with a strategic analysis of the impact of COVID-19. Simultaneously, this research investigated the marketplaces of significant nations and presented their market potential.

Key Questions Answered in the Global Vibration Level Switch Market In Healthcare Market Report are:

What are the most potential high-growth prospects in the worldwide Global Vibration Level Switch Market In Healthcare industry, broken down by product category, End User, and Region?

Which Global Vibration Level Switch Market In Healthcare market categories will grow the most rapidly, and why?

Which regions will grow faster, and why?

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About Us:

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Email: [email protected] Phone No.: +91 9607365656 Website: www.maximizemarketresearch.com

#Global Vibration Level Switch Market

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trumen-indore · 2 years ago

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Trumen came into existence in 2009 and initially started with manufacturing of Tuning Fork Level Switches for liquid and solid applications. With time, the manufacturing range increased with addition of Capacitance Level Transmitter & Capacitance Level Switches, RF Admittance Level Switches, Rotating Paddle Level Switches, Conductivity Type Level Switches, Vibrating Rod Level Switches, Hydrostatic Level Transmitter, Radar Level Transmitter & Ultrasonic Level Transmitter. Trumen is a technocrat driven organization aimed at providing top-of-the-range and high quality level measurement and process control instruments. Formed by the pioneers who devoted their respective lives in development, design and delivery of solution to the problems faced in the field of level sensing and process measurements. Trumen has a fixed point agenda about "sensing matters", and each device created at Trumen is thoroughly tested to pass the quality norms set in-house, in order to give the best performance in all operating conditions.

Address: 39, Mangal Nagar, Behind Sai Ram Plaza, Near Rajeev Gandhi Circle, AB Road, Indore, Madhya Pradesh 452001

Web: https://trumen.in/

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pressreleasestrendsz · 2 years ago

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Food and Beverage Position Sensors Market - Forecast (2022 - 2027)

Food and Beverage Position Sensors market

is anticipated to reach $307 million by 2026 at a CAGR of 7.1% during the forecast period 2021-2026. A position sensor is a sensor that allows mechanical position to be measured. Position sensors are an essential component of many industrial processing and monitoring setups including steam generator, water tube boilers, industrial boiler and others. Manufacturers' increased emphasis on accurate measurements and detailed inspection, technological advancements in position sensors, increased demand for cost-effective and highly efficient position sensors, and growing investments by major players in developed countries are the factors that are expected to drive the global market's growth. The growing need for automated systems with higher accuracy and productivity will drive significant expansion in the F&B position sensor market. The sensor assists the maker in tracking the quality of food and beverages in real time. Furthermore, the introduction of

internet of things (IoT)

based sensors will assist F&B producers in monitoring product quality from a long distance, which would drive the F&B position sensor market. Hence, these factors will drive Food and Beverage Position Sensors market size in the forecast period 2021-2026.

Food and Beverage Position Sensors Market Report Coverage

The report:

“Food and Beverage Position Sensors Market – Forecast (2021-2026)”

, by IndustryARC covers an in-depth analysis of the following segments of the Food and Beverage Position Sensors market.

By Product Type:

Contact and Contact-Less

By Position Sensor Type:

Ultrasonic, Radar Microwave, Tuning Fork, Electromagnetic, Capacitance, Others

By Measuring Type:

Point Level Measuring and Continuous Level Measuring

By Geography:

North America (U.S, Canada, Mexico), Europe(Germany, UK, France, Italy, Spain, Russia and Others), APAC(China, Japan India, SK, Aus and Others), South America(Brazil, Argentina and others) and RoW (Middle east and Africa)

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Key Takeaways

Rising trends towards automation in food and beverage vertical is anticipated to propel the market growth.

The market expansion of the Food and Beverage Position Sensors Market is expected to be aided by technical improvements in position sensors as a result of the rising demand from the food and beverage sector.

Food and Beverage Position Sensors Market Segment Analysis- By Product Type

This market is segmented into Contact and Contact-Less on the basis of product type. Contact less segment is anticipated to witness a significant amount of growth in the forecast period 2021-2026. The benefits of Contact-less position sensors, such as longer life, reduced wear and tear, unmatched precision, consistent outstanding performance, rapid reaction, and suitability for a variety of settings, are attributed for the market's rise. Furthermore, non-contact position sensor applications in precise motion control, robotic movement, MEMS accelerometers, vibration monitoring, and other applications help to drive market expansion. The market for Contact-less position sensors is expected to expand due to reasons such as usability in precise measurement, contamination resistance, and high accuracy. Hence, such factors is analyzed to boost the market growth in 2021-2026.

Food and Beverage Position Sensors Market Segment Analysis- By Position Sensor Type

By Distribution channel, Food and Beverage Position Sensors market is segmented into Ultrasonic, Radar Microwave, Tuning Fork, Electromagnetic, Capacitance, Others. Ultrasonic position sensor held the highest market share in 2020. Higher working temperatures and pressures, as well as the presence of steam and potentially corrosive chemicals such as alcohol and solvents, need the use of strong measurement components that can perform reliably under extreme circumstances. Similarly, as machine footprints get smaller, there is a greater demand for sensors that take up less space. All of these aspects have driven the creation of a new line of ultrasonic sensors that will allow producers to achieve optimal performance in a number of food and beverage applications. Ultrasonic sensors have a stainless steel or alumina exterior construction that optimizes performance while adhering to strict food safety requirements. Accurate sensing is critical in applications such as milk metering and beverage distribution to guarantee proper container filling. Ultrasonic metering is a great way to improve accuracy while keeping a small footprint. Thus, above mentioned factors are analyzed to drive the market growth.

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Food and Beverage Position Sensors Market Segment Analysis- By Geography

APAC held the highest market share of 37% in 2020. The rising need for cost-effective and highly efficient position sensors from the food and beverage industries, as well as technical advancements in optical position sensors, are driving expansion in this area. North America region is anticipated to witness a significant amount of growth in the forecast period 2021-2026. Growing spending by key players in the development of position sensors, as well as an increase in the use of position sensors for level measurement in large alcohol tanks, are contributing factors to market growth in this area. Moreover, the growing number of restaurants, fast-food chains, and meal delivery apps such as grub hub, caviar, and others increase customer access, resulting in substantial development in the food and beverage business in this region. Furthermore, growing consumer desire for organic, natural, and fresh foods as a result of increased health consciousness is a significant driver predicted to boost demand for the food and beverage industry. Because of the shift in consumer food consumption trends and inclination toward a healthy lifestyle, the United States is witnessing a strong demand for gluten-free drinks, followed by Canada and Mexico. Consumers in the United States have good opinions of healthful food items, which may drive market expansion. The favorable regulatory environment, attempts by the Food and Drug Administration (FDA) to encourage gluten-free diets, and further subsidy allocations are expected to enhance the regional market throughout the projected period. The major element driving the strategy of Food and Beverage firms is the constantly altering customer trends. Consumers' lifestyles are changing, and there is a greater demand for processed and ready-to-eat meals, which is fueling the expansion of the food and beverage industry in this area. Thus with the rise of market for food and beverages, the market for position sensors also develops.

Food and Beverage Position Sensors Market Drivers

Increasing focus of manufacturing industry on accurate measurements and detailed inspection are anticipated to drive the market growth

Rising trends towards industrial automation tends to boost the market growth during the forecast period

Manufacturers in every industry are always under pressure to boost earnings while lowering expenses. Furthermore, the food and beverage sector is under pressure to adhere to FDA and other food safety and quality requirements. Automation is an obvious way to alleviate these constraints, since automated processes have been shown to boost efficiency, improve traceability, and preserve the brand's reputation while adhering to the necessary laws. According to the World Health Organization, 600 million people worldwide become unwell after eating contaminated food each year, with 4,20,000 deaths, resulting in the loss of 33 million healthy years. As a result, rising concerns about food safety and cleanliness have driven the use of automation in the food and beverage sector to maintain sanitary standards. This in turn drives the market growth for position sensor market.

Food and Beverage Position Sensors Market Challenges

High cost of ownership restrains the market growth

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Food and Beverage Position Sensors Market Landscape

Technology launches, acquisitions, Partnerships and R&D activities are key strategies adopted by players in the Food and Beverage Position Sensors market. In 2020, the market of Food and Beverage Position Sensors industry outlook has been fragmented by several companies. Food and Beverage Position Sensors top 10 companies include:

Hauser Management AG

GEMS Sensors Inc

First Sensor AG

ABB Ltd

Siemens AG

Endress

SICK

PCB Piezotronics

IFM

TR Electronics

Turck, among others.

Acquisitions/Technology Launches