Flir's acoustic imaging innovation, designed for swift leak detection, offers manufacturers an effective solution for resolving hidden air and gas leaks. By seamlessly converting these invisible energy losses into tangible savings, the technology enhances safety throughout the production process.
The global glass industry, valued annually at over $120 billion, is divided into segments like flat glass, container glass, and specialty products. Over the past few decades, the industry has seen considerable change. In the early 1970s, traditional manufacturing, such as the sheet and plate glass processes, was common.
However, the emergence of float glass plants in Europe, North America, and Japan during the mid-1970s marked a shift, improving the quality of glass surfaces, reducing costs, and allowing for larger sheet production.
Innovations in glass processing
Driven by environmental and ecological crises, the glass industry has remade greatly over the last 50 years
The 1980s and 1990s brought further diversification and innovation with high-performance products and energy-efficient building materials.
Coated and insulated glass units, featuring low-emissivity coatings of metal oxide, became prevalent, balancing solar heat gain control with transparency. These advancements laid the foundations for energy-saving glass prevalent in the market.
Driven by environmental and ecological concerns, the glass industry has transformed significantly over the last 50 years. While earlier practices were heavily fossil-fuel dependent, modern advancements in automation, robotics, and digital control have revolutionised production. Features like computer-controlled furnaces and automated cutting systems have improved efficiency, consistency, and reduced waste, enhancing the overall output.
Addressing the issue of air leaks
In glass production, compressed air is vital yet often overlooked, used for actuating valves, powering tools, and more. Despite its importance, leaks can lead to significant energy loss, increased utility costs, and diminished product quality. A small leak in a system operating for 8,000 hours annually can cost up to 2,800 Euros. Addressing the challenge of identifying such leaks is crucial for optimising production.
A small leak in a system operating for 8,000 hours annually can cost up to 2,800 Euros
Flir, renowned for its thermal and acoustic imaging solutions, has developed the Si2-LD acoustic camera, simplifying the leak detection process. Equipped with ultra-sensitive microphones, this handheld device detects even minor leaks, allowing engineers to perform inspections safely and without halting operations.
Covering a frequency range of 2–130 kHz, it ensures accurate leak identification in various settings. Additional LED lights aid in component identification even in low-light conditions.
Expanding detection capabilities
The Si2-LD acoustic camera goes beyond detecting compressed air leaks; it also identifies leaks of oxygen, nitrogen, ammonia, and other pressurised gases used across industries. Beyond the financial cost of gas loss, the safety risks associated with gas accumulation underline the importance of prompt detection.
With Flir's latest technology, companies can reliably detect leaks, reducing air and gas consumption and enhancing safety. This approach not only ensures cost-efficiency but also addresses serious safety and environmental concerns within the industrial sector.
Flir’s acoustic imaging technology helps manufacturers find and fix leaks fast, turning invisible losses into measurable energy savings and improved safety across every stage of production.
Conventional manufacturing methods
The global glass industry is worth over 120 billion dollars a year. The market is generally split into different segments such as flat glass, container glass and speciality products. The industry has changed significantly in the past few decades.
In the early 1970s, the global glass industry was dominated by conventional manufacturing methods, such as the sheet glass and plate glass processes. However, by the mid-1970s, float glass plants were being built across Europe, North America, and Japan.
The process significantly improved surface quality, reduced production costs, and allowed glass to be produced in much larger sheets, laying the groundwork for the modern architectural glass they know now.
Low-emissivity coatings
During the 1980s and 1990s, the glass industry began diversifying its applications and introducing higher-performance products. In addition, coated and insulated glass units emerged in response to the growing demand for energy-efficient buildings.
Low-emissivity coatings in the form of thin layers of metal oxide applied to the surface, helped control solar heat gain while maintaining transparency. This development was a key step toward the energy-saving glass that dominates the market now.
Digital controls revolutionise production
Simply put, the glass industry has undergone a remarkable transformation over the past 50 years. Many of these changes have been driven by environmental and ecological concerns. This statement applies not only to the end product but also the production process itself.
The heavy reliance on fossil fuels has also changed over the years. The early 21st century saw advances in automation, robotics, and digital controls revolutionise production. Glass manufacturing became more efficient, consistent, and data-driven. Computer-controlled furnaces, real-time quality monitoring, and automated cutting systems improved output while reducing waste.
Losing energy to invisible compressed air leaks
However, one raw material that is often overlooked in the production process is simply air. Compressed air is the invisible workhorse in glass production: actuating valves, driving pneumatic conveyors, powering tooling and purging moulds. It can also be a very expensive utility, and leaks are the stealth tax! In glass plants, where production runs are long and compressed-air demand is high, even a small hole can mean large energy losses, lower line pressure and compromised product quality. A 3 mm diameter leak in a system operating at 6 bar for 8,000 hours per year can cost in the order of 2,800 Euros.
It could be considered somewhat of an irony that an industry that has made such advancements in energy conservation is still using fossil fuels to drive compressors simply to have the air leak out into the environment.
Many of the leaks encountered in a large production unit are difficult to find. In fact, the real challenge is not performing the remedial action, it’s locating the leaks in the first instance.
Detect, quantify, and prioritise leaks with acoustic imaging
Flir is a global leader in the design and manufacture of portable thermal and acoustic imaging cameras. The handheld, lightweight Si2-LD acoustic camera makes leak detection simple: just point the device toward a potential gas or air leak, and its ultra-sensitive microphones detect even the smallest discharges.
This allows engineers to inspect reliably from a safe distance, and without halting operations. The powerful microphones cover a wide frequency range of 2–130 kHz, ensuring precise detection across diverse environments.
As many production areas are dimly lit, the Si2-LD aso includes two powerful LED lights that make component identification quick and easy, even in the darkest corners of a facility.
Latest technology from Flir
Compressed air isn’t the only pressurised gas the Flir Si2-LD can detect. With its integrated software, the camera can also identify and quantify leaks of oxygen, nitrogen, ammonia, and other gases commonly used across industrial environments.
Of course, the cost of lost gas is only part of the problem. Many of these gases pose serious safety risks if allowed to accumulate, increasing the potential for fire hazards or toxic conditions with potentially severe consequences.
See how the latest technology from Flir can help in identifying leaks, lower compressed air and gas usage and improve safety in the organisation.
