Radwell International’s Blog

Human-machine interfaces are everywhere. We interact with machines in almost every aspect of our lives today, whether using self-service checkout at the grocery store, plugging an address into our car’s GPS, or getting cash at the ATM.

What are Human Machine Interface (HMI) Products?

In a manufacturing facility, human-machine interface products (HMI) control automation equipment in an industrial environment. They can range from a simple design with basic screen controls to a more complex touchscreen with numerous features and windows. In most environments, whether for service-oriented tasks or in an industrial environment, HMI systems must be resistant to dust, water, moisture, high or low temperatures, and even chemicals.

All over the world, manufacturers in the glass fiberizing and glass wool industry are interested in increasing the quality of their products. The Gedevelop GFM System is suited for this process. It works with glass flow and collects data in real time for optimum control of the manufacturing process. This system reduces material costs and shortens production downtime.

How exactly does this system work? The Gedevelop system uses a camera which looks at the glass stream and reads information for stream diameter and stream velocity. The information is then sent to the central unit and based on set parameters, calculates the glass flow. The glass flow meter continuously measures glass flow individually for each fiberizing unit and allows the pull to be controlled within .5%. It also checks that the quality of the glass stream is at the correct level and if it isn’t, the system can make adjustments. This glass flow meter is a
non-contact, optical measurement system that calculates the flow of molten glass that falls from the bushing into the fiberizer. Many installations worldwide have proven that glass flow measurement is a very profitable investment in a short amount of payback time.

One of the repair services we provide for our customers at Radwell International is CNC spindle drive retrofits. This service is something that is designed to not only provide cost savings for our clients but also extend the life of a CNC machine tool without requiring an entire machine retrofit. We recently caught up with Mark Councilman, the CNC Sales Manager at Radwell International, based out of our Arlington, Texas location. Mark is a CNC Subject Matter Expert and has been working in the CNC area for 17 years. We had the chance to discuss a bit about CNC machines and how CNC Spindle Retrofits can save time and money for a manufacturing environment.  

What is your role at Radwell International?

My role as CNC Sales Manager is to develop & implement strategies for production, distribution, inside/outside sales, and marketing that position Radwell as a leader in the CNC support market. Currently, my day includes gathering information as I research the CNC market. Typically, I’ll review and validate current pricing on the website and process requests for CNC parts as they trickle in from ASM’s, ISM’s, and customers. I might reach out to Alan Gage with an opportunity for Radwell Verified Subs, and/or seek support from Todd Radwell for a list of parts that should be targeted for pre-certification. The facilities I worked in specialized in exchange and repair of motors, drives, power supplies, CRT’s, and control boards for the CNC market. That's how I came to be considered a subject matter expert in this area.

For many manufacturers, the prospect of moving towards eco-friendly solutions and innovations such as renewable energy is very much front of mind; however, actually implementing the necessary changes is easier said than done. Luckily, as technology develops, and the appetite for carbon neutrality increases around the globe, there are many options for saving not only the bottom line, but the environment.

It’s been 51 years since the birth of the Programmable Logic Controller. We look back at the history of the PLC and how replacing hard wired relay systems changed the world of manufacturing.

It was the year 1964 when a young cunning engineer, Dick Morley, was unemployed, had a new baby, a mortgage to pay and only $1,000 in the bank. Morley had previously worked a desk job designing atomic bombs, aeroplanes and communication systems performing the duties he was instructed to do. Morley did not enjoy his job, and, at that time, he had no plans in the pipeline to create such an influential piece of automated equipment. After finding his passion for skiing, Morely quit his job and focused on his hobby which eventually lead him to engineering ideas.

Morley eventually opened up his own professional consulting firm with friend Geogre Schwenk under the name ‘Bedford Associates’’ located in Bedford, Massachusetts, USA. Morley and Schwenk worked with local machine tool firms to help them evolve into the new, solid-state manufacturing sphere. Unfortunately, as his firm progressed, he began to notice that each project he worked on was practically the same; the manufacturing industry was using similar minicomputers and Morley found himself bored.

With his creativity and his engineering motive to ‘make things work’, Morley started to wonder if he could invent a controller which could automate industrial process with multiple input/output arrangements in real time. This would alternately replace the likes of hard wired relay control systems.