Arjowiggins is a leading international paper production group which manufactures and supplies products ranging from paper for dictionaries to packaging for cosmetic products and security papers. The group has worldwide production sites and employs approximately 8,000 people.
The origins of Arjowiggins France are rooted in ancient local paper mill traditions going back to the 18th century, when Arjowiggins’ predecessors invented the watermark.
The huge Arjowiggins plant at Bessé-sur-Braye (Le Mans region, north east of France) is one of the group’s main plants in France. It has some 700 employees. The site produces coated papers for the group’s Printing and Writing division. Coated paper is treated with a clay based material for special printing finishes. Two-sided, coated wood-free papers have to meet high-quality requirements. They are used for art editions, marketing materials or selective printed magazines, among others.
The production of paper is very energy intensive and it creates large amounts of heat. First the basic mixture, which mainly consists of wood pulp plus additives, is formed and pressed. After the sheet formation process, pressing cylinders remove water. Further drying takes place while the paper is passed around a whole series of cast-iron cylinders heated to temperatures in excess of 100°C. The water content is then lowered to its final level of 1 to 2 %. After the drying process and before the rolling, surface treatment such as calendaring or coating is done.
Monitoring the production process
The drying stage is one of the most difficult parts of the paper manufacturing process. The more the paper dries, the more the drying process on the rolls has to be as equal and uniform as possible. Arjowiggins’ technicians use a FLIR Systems infrared camera to verify the uniform spread of temperature on the rolls. As an instrument able to scan entire surfaces, the camera is an excellent instrument to display variations in moisture distribution.
“The visual information is more important for us than the mere temperature indication”, says Pascal Oger, Technical Assistant and main thermographer at the plant. “The higher the camera resolution and the broader the Field of View, the better”, he adds. “We have a ThermaCAM P-series with a 320x240 pixel resolution combined with a wide angle lens. An investment, but it enables us to see the entire huge paper roll from a few meters distance.”
If the drying process happens according to a regular pattern, no extra drying is needed, which substantially saves energy, and thus production costs. Based on the data provided by the ThermaCAM P-series camera, plant engineers can adjust the drying heaters for optimum product uniformity. The company-owned P-series camera is frequently used at two other Arjowiggins plants in the area.
Another frequent application of thermography is the monitoring of vapour distribution. Observing the condensate return after the vapour distribution gives a good indicator of the rational or non-rational use of the thermal resources. It enables the engineers to use less energy for an identical drying process. This way, the ThermaCAM P-series camera contributes to making the production leaner.
Maintenance and product quality inspection
At manufacturing plants, infrared cameras are often introduced either by the maintenance or the production department. Infrared thermography has always had a good stance at the Arjowiggins group. At the plant in Bessé, the benefits of infrared have been discovered as early as 1997, when the company purchased its first cameras from AGEMA, the predecessor company of FLIR Systems.
Predictive maintenance of electrical installations and machines at the huge plant is outsourced to an external infrared thermography consultant, who has the required time, equipment and expertise to make and present his reports to the technical staff.
Using the P-series camera
Pascal Oger mentions the laser pointer, which is standard equipment on the P-series camera, as a very practical and safe tool for his applications as well as the flexible handling of the camera’s big screen. Oger stores his images on a set of Flash cards, using one card for each plant he inspects in the course of a week.
“We are happy with the camera and its features, and we see the substantial savings generated by infrared thermography every day”, says Pascal Oger, who, meanwhile, is turning the search of building and isolation deficiencies at the plant into some kind of a hobby. “However”, he adds, “I am aware that we do not yet use the full potential of infrared thermography here at our plant. But we will do more soon, as a cost-benefit analysis has prompted us to participate in a certified Infrared Training Center (ITC) course.”
About Infrared Thermography
Thermal imaging, also called thermography, is the production of non-contact infrared or “heat” pictures from which temperature measurements can be made. Portable infrared cameras scan equipment and structures, then instantly convert the thermal images into pictures in a JPEG format for monitoring and analysis. Thermal imaging increases efficiency and maximizes safety in many industries and environments and is rapidly expanding into new markets.
About FLIR Systems
FLIR Systems is the world leader in the design and manufacturing of infrared cameras. The company has over 40 years of experience and more than 50,000 infrared cameras currently in use worldwide for applications including predictive maintenance, research & development, process monitoring, automation and many others. FLIR Systems has four manufacturing plants located in the USA and Sweden and operates direct sales offices in Belgium, France, Germany, Italy, the United Kingdom, China, Japan and Australia. The company numbers over 1,300 dedicated infrared specialists, and serves international markets through a network of 60 regional offices providing sales and support functions.