Reliable Capacitance Level Transmitter for Accurate Industrial Level Measurement

A Capacitance Level Transmitter is a high-precision device designed for continuous and accurate measurement of liquid and solid levels in industrial tanks, silos, and process containers. Utilizing advanced capacitance technology, this transmitter ensures reliable performance in various industries, including chemical processing, water treatment, food and beverage, pharmaceuticals, and oil & gas.

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Top-Quality Boot Level Switch & Capacitance Level Transmitter by Levtron

Discover industry-leading boot-level switches and capacitance level transmitters at Levtron. Engineered for accuracy and long-term performance, our level measurement devices are ideal for critical industrial environments. With advanced features and robust design, Levtron products help streamline operations and improve measurement reliability.

Reviving Tesla’s Dream: The Future of Wireless Power Transmission

“My project was retarded by the laws of nature. The world was not prepared for it. It was too far ahead of time. But the same laws will prevail in the end and make it a triumphal success.” – Nikola Tesla

In the early days of radio technology, there was a crucial decision point that split wireless technology into two distinct paths. One path, pursued by Marconi and others, focused on electromagnetic wave transmission. The other path, championed by Nikola Tesla, aimed to minimize electromagnetic waves and use the Earth itself for energy transmission. While the world predominantly embraced the former, Tesla’s innovative approach was largely forgotten. Let’s explore Tesla’s lost art.

Tesla's wireless power transmission system, often known as his "Magnifying Transmitter," was a pioneering approach to sending electrical energy over long distances. Unlike today’s wireless technologies, which rely on electromagnetic waves, Tesla's design aimed to transmit energy through the earth, which he believed was more efficient.

Tesla showcased his system’s potential during his 1899 experiments in Colorado Springs. He successfully transmitted energy through the ground, illuminating bulbs about a mile away from the transmitter. Tesla saw this as a matter of engineering: just as a machine that can throw a rock 5 feet can be engineered to throw it 1,000 feet, he believed his system could be adjusted to transmit power across any distance on Earth.

Modern wireless technologies, such as radio, Wi-Fi, and cellular networks, use electromagnetic waves that spread outward from a source. These waves lose strength according to the inverse square law, which means signal strength decreases with the square of the distance from the source. This energy loss is a significant limitation for long-distance communication and power transmission.

Tesla’s vision was quite different. He recognized that while electromagnetic waves were effective for communication, they were inefficient for transmitting large amounts of power. As he put it, “I only used low alternations, and I produced 90 percent in current energy and only 10 percent in electromagnetic waves, which are wasted.” Tesla aimed to minimize electromagnetic radiation, which he considered to be energy-draining. Instead, he focused on transmitting energy through the earth, which he believed was more efficient and recoverable.

Tesla's system utilized a large coil known as the "Magnifying Transmitter," which generated a high-voltage, low-frequency current. This design featured significant self-inductance and minimal capacitance, producing a strong resonant effect. By accumulating and directing massive amounts of energy with minimal losses, Tesla aimed for efficient power transmission. As he explained, “I accumulate in that circuit a tremendous energy... I prefer to reduce those waves in quantity and pass a current into the earth, because electromagnetic wave energy is not recoverable while the earth current is entirely recoverable, being the energy stored in an elastic system.”

The scientific principles of Tesla's system include:

1. Resonant Circuits: Tesla's system used resonant circuits, tuning the primary and secondary coils to the same frequency. This resonance allowed for efficient energy transfer between coils, amplifying energy while minimizing losses.

2. Self-Inductance: A key component of Tesla’s system was self-inductance. A large coil with high self-inductance generated a strong magnetic field essential for creating high-voltage, low-frequency current. Self-inductance helped store energy in the coil’s magnetic field, critical for high power levels.

3. Capacitance: Tesla’s design involved large capacitors to store electrical energy. Capacitance was kept small compared to self-inductance to achieve desired resonant effects. The capacitors would discharge rapidly, creating high-voltage pulses for transmission through the earth.

To construct a system similar to Tesla’s, he advised:

1. Low Frequency, High Voltage Design: Build a large Tesla coil to generate high voltages at low frequencies. Ensure the design minimizes electromagnetic radiation and focuses on efficient energy transfer into the ground.

2. Loose Coupling for Resonance: Use loose coupling between the primary and secondary coils to achieve significant resonant rise. The coils should be inductively linked but not too close to avoid direct energy transfer.

3. Earth Connection: Establish a deep, effective ground connection to allow the transmitter to send electrical currents into the earth, utilizing its natural conductive properties.

4. Minimizing Radiation: Design the system to suppress electromagnetic radiation, aiming to retain energy within the circuit and direct it into the ground. Tune the system to maximize energy storage and transfer.

5. Energy Storage and Discharge: Incorporate large capacitors for storing and rapidly discharging energy to create high-voltage, low-frequency oscillations.

Tesla’s system faced significant challenges, including the need for large, expensive equipment. In 1914, he estimated the cost of his "Magnifying Transmitter" at $450,000—around $15 million today. These financial constraints prevented him from fully realizing his dream and unfortunately led to his public image as a mad scientist with unrealistic future visions. However, the potential applications of his system are vast, from global wireless power transmission to reducing infrastructure costs and powering remote areas. With ongoing advancements in technology, Tesla’s vision may be within reach.

Tesla’s system presents an alternative approach to wireless energy transmission, focusing on efficiency and long-distance power transfer over the broad dispersal of electromagnetic waves. While modern technologies have advanced in different ways, Tesla’s principles—especially his focus on resonant circuits and earth currents—provide valuable insights into alternative methods of energy transmission. Exploring these principles today could lead to innovative applications, such as more efficient long-distance power transmission or new energy transfer methods.

Trumen Technologies Pvt. Ltd.” is an ISO 9001:2015 certified ,Indian based Manufacturer and Exporters of Level and Pressure sensing instruments. We at Trumen is a team of professionals having years of experience in Level and Pressure Instruments manufacturing who understands what customer needs, and try to fulfill those requirements in appropriate time with best Quality.

 We have wide range of CE certified product like Radar Level Transmitters, Ultrasonic Level ,Vibrating fork solid level switch, Vibrating fork liquid level switch, Admittance point level switch, Capacitance point level switch, Vibrating rod point level switch, Conductivity point level switch, Capacitive continuous level transmitter, Hydrostatic continuous level transmitter, etc.

 Our products used in different industrial applications in various industries like Power and Water, Oil and Gas, Petrochemical, Mining and Metal, Food and Beverages, Cement ,Pharmaceutical and many more. We are regularly supplying our products to NTPC, IOCL,BPCL, BORL, Cipla, Lupin, Cadila healthcare, Praj High Purity Systems , Ultratech Cement, Shree Cement ,Jindal Group ,TATA, Asian Paints, Procter & Gamble, Hindustan Unilever Ltd, Kirloskar, Vedanta, Nestle, Pepsi, BASF, Novartis and many more.

We are regularly exporting our products to USA, UK, South Korea, Italy ,Thailand, Taiwan, UAE, Tanzania, Turkey ,Sri Lanka ,Saudi Arabia , Kuwait ,Malaysia, Sweden, Canada, Egypt , Brazil ,Singapore etc.

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

Web: https://trumen.in/

Contact: 0731 497 2065

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How Ultrasonic Level Transmitter Enhances Measurement Accuracy

In an industrial world, precision in measurement systems is a necessity for effective and safe operation. Probably the most evident technology that can guarantee such precision is the Ultrasonic Level Transmitter. It is a device specifically designed to give accurate, non-contact level measurements. This makes it a vital part of any industry from manufacturing to water treatment. Let's examine how ultrasonic level transmitters improve the precision of measurement and why they're a necessity in modern applications.

An ultrasonic level transmitter sends high-frequency sound waves to the surface of a material. These waves are reflected back to the transmitter and, based on the time of travel for the echo to get back, calculate the distance from the transmitter to the surface.

These types of ultrasonic level transmitters work without touching the material, which means they are also ideal for measurements involving hazardous substances, corrosives, or even unstable materials. Key Features To Improve Accuracy

No Contact Measurement The no-contact feature of the ultrasonic level transmitters excludes errors due to material buildup and wear and tear. Since there is no actual contact between the sensor and substance being measured, it ensures good and reliable performances over time.

Advanced Signal Processing Modern ultrasonic level transmitters, including versions offered by Nikeson, contain sophisticated signal processing algorithms. The algorithms filter out noise, reflections, and disturbances caused by environmental factors to provide accurate measurements even in difficult conditions.

Flexibility for Diverse Environments The ultrasonic level transmitters are designed to work effectively in a wide range of conditions. High temperatures, changing pressure levels, or extremely high humidity conditions will not affect their accuracy. The strength in the construction is what safeguards these sensors from being affected by extraneous elements that may affect standard sensors.

Measurement Range Ultrasonic level transmitters measure the levels over a wide range. This is appropriate for use both in small tanks and large industrial silos. Versatility is thus assured with regard to size of application and, by virtue of that, accurate reading is ensured.

Applications Served by Ultrasonic Level Transmitters

Industrial Manufacturing Measurement of levels for oil and gas, chemicals, and food processing industries holds a special importance in the context of efficiency in production and material loss, but an ultrasonic level transmitter provides assured liquid monitoring for solids and slurries.

Water and Wastewater Management It is effective in the monitoring of reservoirs to the wastewater treatment plants; it ensures effective activities are done. It is efficient in delivering real-time information in assisting decision making that pertains to optimal resource use and meeting regulation requirements.

Agriculture Fertilizer Management Ultrasonic level transmitters in agricultural farms and facilities measure fertilizers, water, and pesticides at a precise level to prevent wasteful use whereby maximum productivity is achieved.

Benefits Over Traditional Measurement Methods

Maintenance-Free Operation A traditional measurement system, such as a float sensor or capacitance probe, experiences material buildup or wears out, resulting in frequent maintenance. Ultrasonic level transmitters are non-contacting devices, almost maintenance-free in nature.

Cost Savings Ultrasonic level transmitters save more money in the long run, since they decrease the need for frequent maintenance while offering long term reliability.

Enhanced Safety In dangerous environments, such as chemical plants or fuel storage facilities, the risks are minimized by avoiding direct contact with dangerous substances by using ultrasonic level transmitters.

Why Choose Nikeson Ultrasonic Level Transmitters? Nikeson's Ultrasonic Level Transmitter offers unmatched accuracy, durability, and ease of operation. Due to its remote type design, flexibility in installation and operation can be enjoyed for a wide range of applications.

Some of the notable features of Nikeson ultrasonic transmitters include the following:

Accurate measurement for both liquids and solids. Strong structure to operate under extreme conditions. Advanced technology for no interference and reliability. To know more about Nikeson's products, go directly to its Ultrasonic Level Transmitter page. The Ultrasonic Level Transmitter is a game-changing tool for accurate and efficient level measurement. Non-contact technology, adaptability to challenging environments, and cost-effectiveness make it an essential asset for industries around the world. Investment in reliable solutions such as Nikeson's ultrasonic level transmitters allows businesses to optimize operations, reduce costs, and enhance safety.

Discover the entire range of ultrasonic solutions and experience the future of level measurement today!

Reliable Hopper Level Switch – Precision Monitoring for Bulk Solids & Liquids

The Hopper Level Switch is a crucial component in bulk material handling systems, ensuring precise level detection for powders, granules, and liquids. Designed with vibrating fork technology, it provides accurate and reliable monitoring in hoppers, silos, and storage tanks.

Why Choose a Hopper Level Switch? Industrial processes require precise level control to prevent overflow, maintain efficiency, and optimize operations. The compact vibrating fork level switch from Levtron ensures high-precision level measurement, making it ideal for industries such as cement, food processing, pharmaceuticals, chemicals, and power plants.

Key Features:

✅ Non-Contact Sensing: The vibrating fork technology offers accurate detection without material build-up. ✅ Versatile Applications: Suitable for powders, granules, and liquids in hoppers and storage tanks. ✅ High Sensitivity & Reliability: Works efficiently with low-density and high-viscosity materials. ✅ Robust & Durable: Designed for harsh industrial environments, ensuring long-lasting performance. ✅ Easy Installation & Maintenance: Simple integration with existing automation systems.

Applications of Hopper Level Switches

1️⃣ Cement & Aggregate Industry: Ensures smooth material flow in hoppers and silos, preventing blockages. 2️⃣ Food & Beverage Processing: Maintains precise ingredient levels in storage containers. 3️⃣ Chemical & Pharmaceutical Manufacturing: Ensures accurate bulk powder handling for production safety. 4️⃣ Power & Energy Sector: Monitors coal, fly ash, and biomass levels in storage tanks.

Why Choose Levtron?

Levtron offers cutting-edge level sensing solutions that meet industry demands for accuracy, durability, and efficiency. Their compact vibrating fork level switch ensures uninterrupted operations with minimal maintenance and maximum reliability.

🔹 Upgrade Your Process Control Today! Choose the best hopper level switch for accurate and efficient level detection in industrial applications. Visit Levtron now!

Capacitance Level Transmitter for Accurate Liquid and Solid Level Measurement

The Capacitance Level Transmitter is a highly reliable and accurate instrument designed to measure the level of liquids, solids, and slurry in various industrial applications. This non-contact level measurement technology is ideal for monitoring challenging materials such as powders, bulk solids, and liquids with high viscosity or foam. Offering precise and continuous level monitoring, our Capacitance Level Transmitters are perfect for industries like chemical processing, food & beverage, pharmaceuticals, and oil & gas.

Our advanced capacitance technology provides accurate readings, reducing maintenance requirements and enhancing operational efficiency. With a robust design, these transmitters are engineered to perform in harsh environments and extreme conditions. Easy to install and configure, the Capacitance Level Transmitter ensures stable and reliable performance over long periods.

Whether you need to measure the level of liquids, granules, or slurries, our capacitance-level transmitters offer versatile and dependable solutions for your process control needs. Explore our range of transmitters and find the perfect match for your application.

Wireless Charging for EVs: Exploring Innovative Methods and Technologies

With electric vehicles (EVs) gaining traction in the Indian market, enterprises are rapidly upgrading supporting infrastructure to make EV ownership more convenient and encourage broader adoption. This transition not only benefits drivers but also accelerates the shift toward a sustainable, carbon-free energy future.

Charging remains the cornerstone of EV infrastructure, and significant advancements have been made to improve this aspect, including the introduction of wireless electric charging.

Yes, EV owners can now enjoy the convenience of charging their vehicles without plugging them in—similar to wireless phone charging. This innovation brings new levels of efficiency, speed, and uninterrupted transportation, paving the way for a seamless driving experience.

In this blog, we’ll explore the different types of wireless EV charging architectures.

Types of Wireless Electric Charging

Wireless EV charging can be categorized into two main modes: static and dynamic, each offering unique advantages and applications. Let’s dive deeper into these methods and other technologies that make wireless EV charging possible.

1. Static EV Charging (Home or Office Charging Stations)

Static charging systems require the vehicle to remain stationary during charging. Similar to traditional wired charging, these systems use induction to transfer power wirelessly.

When an EV is parked over the designated wireless charging area, transmitters embedded under the asphalt transfer power to the receivers installed beneath the vehicle's chassis. This system is ideal for home garages, office parking lots, and other stationary locations.

2. Dynamic EV Charging (Roadways and Highways)

Dynamic charging takes wireless charging roads a step further by allowing vehicles to charge while in motion. Using mechanisms similar to static systems, dynamic charging operates seamlessly without speed constraints.

This innovation enables EV owners to drive long distances without worrying about depleting battery power. While the concept of dynamic charging roads holds immense promise, building this infrastructure requires significant investment and remains a vision for the future.

Innovative Wireless Charging Systems

Wireless EV charging isn’t limited to static and dynamic methods. Advanced technologies provide a variety of ways to wirelessly transfer energy to EVs:

1. Capacitive Wireless Charging System (CWCS)

In this method, energy is transferred wirelessly via a displacement current generated by an oscillating electric field. Instead of traditional magnets and coils, coupling capacitors facilitate the transfer.

How It Works:

A power factor correction circuit first processes the AC voltage for efficiency and stability.

The voltage is converted to high-frequency AC using an H-bridge, which creates an oscillating electric field.

This field induces displacement current at the receiver, which is then rectified and used to charge the EV battery.

2. Permanent Magnet Gear Wireless Charging System (PMWC)

In the PMWC system, both the transmitter and receiver feature armature windings and synchronized permanent magnets.

How It Works:

The transmitter, acting as a motor, uses AC current to create mechanical torque, rotating its magnet.

This rotation induces synchronous movement in the receiver’s magnet through magnetic interaction.

The receiver generates AC current, which is rectified and converted to DC to charge the EV battery.

3. Inductive Wireless Charging System (IWC)

Inductive charging relies on Faraday's law of induction to transfer power. This method uses mutual induction between transmitter and receiver coils.

How It Works:

An AC magnetic field generated by the transmitter coil induces power in the receiver coil.

The resulting AC output is filtered and rectified to charge the battery.

The efficiency depends on factors like frequency, mutual inductance, and the distance between coils. Inductive systems typically operate between 19 and 50 KHz.

4. Resonant Inductive Wireless Charging System (RIWC)

Resonant inductive systems use high-quality resonators to transmit energy efficiently over longer distances. Maximum power transfer occurs when the resonant frequencies of the transmitter and receiver coils match.

How It Works:

Additional compensation networks (series or parallel) optimize resonant frequency and minimize losses.

These systems operate at frequencies ranging from 10 to 150 KHz, offering higher efficiency for long-distance wireless power transfer.

Wrapping Up

The automotive industry is steadily transitioning to a future where EVs dominate the market. This shift challenges manufacturers to meet strict emission standards and demands the development of robust charging infrastructure.

As the transition from internal combustion engines (ICEs) to EVs unfolds, charging solutions will play a pivotal role in supporting this evolution. wireless charging in electric vehicles, particularly static and dynamic models, are at the forefront of this revolution, offering convenience and efficiency for EV drivers.

At HuseHQ, we are driving this change with cutting-edge wireless charging solutions tailored for homes, offices, and roadways. Our innovative technologies make it easier for facilities, businesses, and residential spaces to transition to an EV-friendly future.

Connect with us today to learn more about how we can help you embrace the future of EV charging.

Understanding Differential Pressure Level Transmitters: How They Work, Applications, and Benefits

In various industrial applications, accurate and reliable level measurement is crucial for maintaining process safety, efficiency, and product quality. One of the most widely used instruments for this purpose is the differential pressure level transmitter. These devices provide an effective way to measure the level of liquids in tanks, vessels, and pipelines by using the principle of differential pressure. In this article, we will explore what differential pressure level transmitters are, how they work, their key applications, and the benefits they offer.

What is a Differential Pressure Level Transmitter?

A differential pressure level transmitter is a type of sensor used to measure the level of liquids within a tank or vessel by detecting the pressure difference between two points. This pressure difference is directly related to the height (or level) of the liquid. By accurately measuring the pressure difference, the transmitter can determine the liquid level and provide valuable data for process monitoring and control.

How Does a Differential Pressure Level Transmitter Work?

The operation of a differential pressure level transmitter is based on the following key principles:

Basic Concept of Differential Pressure: The pressure exerted by a liquid column is directly proportional to its height. The greater the height of the liquid, the higher the pressure at the bottom of the tank or vessel. Differential pressure level transmitters measure the pressure difference between two points, typically the bottom and the reference point at the top or side of the tank.

Pressure Sensing: The transmitter has two pressure ports – one connected to the bottom of the tank (high-pressure side) and the other connected to the top or a reference point (low-pressure side). The high-pressure side measures the pressure due to the liquid column, while the low-pressure side measures the pressure above the liquid, often atmospheric pressure.

Diaphragm Movement: The pressure difference causes a diaphragm within the transmitter to deflect. This deflection is proportional to the differential pressure.

Conversion to Electrical Signal: The deflection of the diaphragm is converted into an electrical signal using various sensing methods such as capacitance, piezoelectric sensors, or strain gauges. This electrical signal is then processed and calibrated to represent the liquid level.

Output Signal: The transmitter provides an output signal (typically 4-20 mA or a digital communication protocol like HART) that corresponds to the liquid level in the tank or vessel. This output can be used for monitoring, display, or control purposes.

Key Applications of Differential Pressure Level Transmitters

Differential pressure level transmitters are versatile and used in various applications across multiple industries:

Chemical and Petrochemical Industries: These transmitters are commonly used in chemical plants and refineries to measure the level of liquids in storage tanks, reactors, and separators. They help maintain proper levels of chemicals, prevent overflow, and ensure the safe operation of processes.

Water and Wastewater Treatment: In water treatment facilities, differential pressure level transmitters monitor the levels of water, sludge, and other liquids in tanks and reservoirs. Accurate level measurement is essential for efficient filtration, sedimentation, and treatment processes.

Oil and Gas Industry: These transmitters are used to measure the level of oil, gas, and other liquids in storage tanks, separators, and pipelines. They help prevent overfilling, detect leaks, and optimize the handling and processing of hydrocarbons.

Food and Beverage Industry: In food processing plants, differential pressure level transmitters monitor the levels of liquids such as milk, juices, and syrups in storage and mixing tanks. Accurate level measurement is critical for maintaining product quality and consistency.

Power Generation: In power plants, these transmitters measure the level of water in steam drums, condensate tanks, and feedwater heaters. Proper water level control is essential for efficient steam generation and safe operation of boilers.

Advantages of Using Differential Pressure Level Transmitters

High Accuracy: Differential pressure level transmitters provide accurate and reliable measurements, even in challenging conditions. This accuracy is crucial for maintaining process safety and product quality.

Versatility: They can be used with a wide range of liquids, including corrosive and viscous fluids, making them suitable for diverse industrial applications.

Cost-Effective: Compared to other level measurement technologies, differential pressure level transmitters offer a cost-effective solution for continuous level monitoring.

Robust Design: These transmitters are designed to withstand harsh environments, including high temperatures, pressures, and corrosive substances, ensuring long-term durability and reliability.

Ease of Installation and Maintenance: Differential pressure level transmitters are relatively easy to install and maintain. They can be installed directly onto tanks or vessels, and their straightforward design allows for simple calibration and adjustment.

Installation and Maintenance Tips

To ensure optimal performance and longevity of differential pressure level transmitters, follow these installation and maintenance best practices:

Proper Positioning: Install the transmitter at a suitable location to avoid errors caused by vibration, temperature fluctuations, or environmental conditions. Ensure that impulse lines are kept short and free of blockages to maintain accurate readings.

Avoid Air Traps: For liquid level measurement, ensure that no air is trapped in the impulse lines, as this can cause inaccuracies in the pressure readings.

Regular Calibration: Perform regular calibration checks to maintain the accuracy of the transmitter. Calibration should be part of the routine maintenance schedule, especially in critical applications.

Inspect for Leaks: Regularly inspect impulse lines, connections, and seals for leaks that could affect the accuracy of the differential pressure measurement.

Check for Clogs: Ensure that the pressure ports and impulse lines are not clogged with debris, sediment, or buildup, which could impede the pressure measurement and lead to incorrect readings.

Conclusion

Differential pressure level transmitters are essential tools for accurate and reliable liquid level measurement in various industrial applications. Their ability to provide precise level data helps maintain process safety, optimize operations, and ensure product quality. By understanding how these transmitters work, their key applications, and maintenance best practices, industries can effectively utilize differential pressure level transmitters to enhance the efficiency and reliability of their processes. Whether in chemical plants, water treatment facilities, or food processing units, these transmitters play a crucial role in modern process control and monitoring systems.

The Trumen TLC Advantage

In critical processes like WFI (Water for Injection) systems, accuracy isn’t just a feature — it’s a necessity. That’s where the Trumen Capacitance Level Transmitter (TLC) shines!

Designed specifically for CIP vessels, the TLC ensures reliable, real-time level measurement to maintain the highest standards of water purity and process efficiency. With its advanced capacitance technology, it delivers:

Unmatched accuracy in challenging environments

Robust performance even in high-purity water applications

By optimizing WFI water management, the Trumen TLC safeguards product quality and compliance with pharmaceutical-grade standards.

Here’s to technology that powers purity and precision!

Contact: 0731 497 2065

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

Website: http://trumen.in/