Desoutter MULTI CVIL II: Uses and Applications for Manufacturing IndustriesApril 18th, 2019
Manufacturing industries, those that feature MULTI CVIL II connectivity, are capable of manipulating many simultaneously operating electro-mechanical processes. That, in a nutshell, is what makes one production line better than its neighbours. Like clockwork, the automated and semi-automated streams of product or service processing components conduct their machine-accurate actions. Making such actions possible, we start with the CVIL Master Unit, which is an integrated solutions hub that optimises production lines.
Sipping The Desoutter Multi CVIL Lifeblood
The metaphorical fluid in question is known as CVIPC2000. This is the spindle manipulating language that’s sent out by the CVIL Master Unit to all its system-attached slave devices. Connectivity is established here and electronically distributed to as many as 32 fixtured spindles. Driving these tools, the equipment brain and its sub-brains can synchronously combine as many as 20 different fastening cycles. Using this digital brain as a hub, Desoutter has designed a comprehensive range of tools, which are designed to assemble any and all product elements.
Establishing A Factory Networks Standard
The Master Multi CVIL II base unit uses a single-line ethernet connection to communicate with its slaves. The Language used is CVIPC2000, the real-time fastener analysis module is called CVINET, and the physical nodes are referred to as Field bus connections. It’s essentially a network, one that crunches assembly instructions and sends those instructions to robotic spindles. But what’s the core instruction set running through the various digital modules? And why is system connectivity such a fundamentally important equipment attribute? Well, Desoutter integrated solutions must be error-free, must deliver productivity-enhanced end-point articles, and they must be absolutely reliable, hence the CVINET analysis module. With reference to the core code, it’s all about the tightening process.
Spindle Assembly Applications
A full synchronisation spindle tightening sequence locks down scores of alternatively sized fasteners. Meanwhile, CVINET checks for tightness and angular deviations. For example, on one manufacturing line, an EME35-10J rotating shaft could apply 1-to-8 Nm of accurately implemented torque, perhaps as used on a circuit board fastener. Moving up the tool scale, an EME106-20J robotic spindle fastens car body parts by calling upon 1900-Nm of torque at 39-RPM. Fragile glass or plastic, tough steel or sheet aluminium, the Multi CVIL II spindles and digital brains deliver fast and productive manufacturer-centric power.
Digital controllers, including Desoutter flavoured variants, are designed to accomplish all of the finite adjustments and incremental actions that are now an essential part of the manufacturing sector. The assembly equipment might look bulky and unwieldy, but it’s deceptively deft. That degree of mechanical acuity starts back at the Multi CVIL II hub, is passed on to the slave units, and it’s carried into a series of hard-working spindles, which work on cars, glass and plastic surfaces, fragile circuit boards, and countless assembly level applications.
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