Getting Smart, Getting Rugged Extending LANs into Harsher Environments

Getting Smart, Getting Rugged Extending LANs into Harsher Environments

Virtually everything we do now on a daily basis touches the network—whether it’s buying a snack, sending an email or taking a ride at an amusement park. The proliferation of digital information, wireless handheld devices and Ethernet into every facet of our lives means that connections to networks need to be in more places than ever before.

With manufacturing environments having rapidly migrated to Industrial Ethernet over the past decade as a means to deliver information for industrial automation and control systems and to integrate factory environments with the corporate LAN, it’s no wonder that the industry is seeing a growing demand for network cables, patch cords and connectors capable of withstanding more severe conditions.

But what about environments that fall somewhere in between—not quite severe enough to be considered “industrial” but in need of something more ruggedized than what exists in everyday commercial office environments? Extending the network into these types of environments is becoming more common than one might think. As our world becomes more digital, these types of environments are popping up everywhere and demanding ruggedized network cables, patch cords and connectors that maintain long-term network reliability and prevent the need to replace components due to corrosion and damage from a variety of elements.

Knowing the Standards – From MICE to NEMA

While standards for industrial environments are certainly applicable to factory floors, manufacturing plants and processing facilities, the same standards can be used to determine the type of ruggedized cable and connectivity required for those in-between environments that are not as clearly identified as either commercial or industrial.

The international standard ISO/IEC 24702 provides application-independent requirements for both balanced copper and fiber optic cable systems that support Ethernet-based data communications in industrial environments. The standard provides implementation options and requirements for cable and connectivity that reflect the operating environments within industrial premises. ISO/IEC 24702, along with its comparable U.S. TIA-1005 and European EN 50173-3 standards, incorporate the MICE method of classifying parameters for the materials needed to build an industrial network.

MICE stands for Mechanical, Ingress, Climatic and Electromagnetic and includes three levels of environmental harshness-level 1 for everyday commercial office environments, level 2 for light industrial and level 3 for industrial. For example, M3I3C3E3 environments require network infrastructure components that are able to withstand the highest levels of vibration, shock, tensile force, impact and bending (see Table 1).

Table 1: MICE Parameters

While the MICE method is used to determine the harshness level of commercial, light industrial and industrial, rarely is an environment exclusive to one MICE classification. Furthermore, one run of cabling from point A to point B can traverse through various MICE classifications along the route. Designers planning cabling systems in harsh environments therefore need to have a good understanding of the environment and what constitutes levels 1, 2 and 3 for each parameter. In some cases, measuring the environment can require specialized equipment, especially when it comes to measuring vibration and electromagnetic interference. The standards include MICE tables to help determine which levels exist within the targeted environment (see Table 2).

The trick to using MICE levels to determine components is to always consider the worst case scenario and worst case level parameter, regardless of the other parameters. For example, an environment exposed to liquid may be classified as M1I3C1E1. If only ruggedized components meeting M3I3C3E3 are available, they may need to be used regardless of whether that level of protection is required for all parameters.

Table 2: MICE Classifications

Another standards-based rating to consider for harsh environments is the ingress protection (IP) ratings developed by the European Committee for Electro Technical Standardization (CENELEC). Sometimes referred to as an IP code, the IP rating consists of the letters IP followed by two digits—the first digit classifying protection against solids (i.e., dust) and the second classifying protection against liquids (i.e., water). For example, as shown in Table 3, an IP rating of IP22 would indicate protection against finger-size objects and vertically dripping water.

Table 3: IP Code Ratings

One of the common IP ratings seen for ruggedized connectivity in our industry is IP66/IP67, which offers total protection against dust ingress and water ingress. While the IP rating is especially useful for determining the level of protection needed when dealing with wet, dusty environments, it’s important to remember the remaining MICE parameters such as ability to withstand higher temperature and humidity ranges or to maintain performance amidst higher levels of electrostatic discharge (ESD) or radio frequency interference (RFI).

Table 4: NEMA Enclosure Ratings and IP Equivalents

There is yet another standard to consider related to enclosures, which can include cabinets, surface mount boxes, floor and ceiling boxes, junction boxes and even network equipment housing. The National Electric Manufacturer Association (NEMA) uses a standard rating system for enclosures that defines the types of environments where they can be used. NEMA ratings for enclosures also have IP code equivalents, as shown in Table 4 that highlights the most common NEMA enclosures.

Identifying the Key Components – From Cables to Connectors

The need for ruggedized connectivity can also relate to fiber outlets in a variety of environments.

When it comes to selecting ruggedized cable and connectivity, both copper and fiber solutions may need to be considered—especially as more fiber is extending out of the commercial data center and telecommunications room environment to bring higher bandwidth closer to the work area outlet or to deal with longer distance requirements.

While not all MICE parameters will relate to both copper and fiber, especially with fiber being immune to electromagnetic interference, the IP66/IP67 rating on connectivity can easily apply to both as can other mechanical, climatic and chemical parameters. In general, ruggedized cable and connectivity solutions for harsher environments should feature components and characteristics such as the following:

Stainless steel faceplates with rear sealing gaskets and dustcaps for unused connections are ideal for protecting critical network connections in harsh environments.

  • Chemical-resistant thermoplastic housing on connectivity — Plugs and outlets should use materials that provide the widest range of protection from most solvents and common industrial chemicals.
  • Dust caps for outlets — Ruggedized dust caps can protect unused outlets and seal outlets during wash downs.
  • IP67-rated copper and fiber connectivity — Ruggedized outlets and modular patch cords with an IP66/IP67-rated seal protect plugs and outlet contacts from dust and moisture.
  • Shielded twisted-pair cabling for copper — Shielded copper cabling such as F/UTP cables and S/FTP cables will provide much higher resistance to EMI/RFI.
  • More durable cable jacket materials — Jacket materials such as polyurethane and thermoplastic elastomers can provide better tensile strength and lower temperature flexibility and brittle points, as well as better tear, abrasion, chemical and moisture resistance.
  • IP44-rated faceplates — Stainless steel faceplates with rear sealing gaskets provide a protective seal from moisture and debris.
  • NEMA 4X enclosures — Enclosures and surface mount boxes with a NEMA rating will protect the termination points of ruggedized outlets.

Making the Best Choice – From Home Plates to Seafood Platters

Dodger Stadium

With the proliferation of digital information, handheld devices and Ethernet, consumers and employees everywhere demand network and Internet access at all times and digital applications that make their lives and jobs easier. Consequently, enterprise businesses are required to expand their networks into places that in the past would have gone without network connections and wireless service. With many of the environments that now need access being outside of the realm of standard commercial environments, enterprise businesses are partnering with manufacturers that offer ruggedized cable and connectivity in addition to commercial-grade components.

Siemon Ruggedized Z-MAX Category 6A shielded IP66/IP67-rated outlets and cords were deployed at Dodger Stadium’s outdoor concession stands and kiosks

In a $150 million upgrade at Dodger Stadium, the 52-year old home of the Los Angeles Dodgers and the third oldest park in Major League Baseball, plenty of enhancements were made to deliver a state-of-the-art experience to fans, including a new high-performance copper and optical fiber cable system to support stadium-wide WiFi, digital displays, IP-based security, box offices, kiosks and pointof-sale locations.

Trident Seafoods

The largest seafood company in the U.S., Seattle-based Trident Seafoods is a vertically integrated seafood company of fishing vessels and processing plants that produce fresh, frozen, canned, smoked and ready-to-eat seafood products under a variety of brand names, including Trident, Louis Kemp and Rubenstein’s. When the company wanted to extend network access throughout its three factory trawlers, they turned to Siemon’s ruggedized connectivity.

Starting with the 276-foot Kodiak Enterprise, Trident sought to upgrade the entire on-board network to not only improve existing wheel house communications, but also to provide whole-ship Wi-Fi for the more than 125-person crew that lives on the ship for extended periods of time during peak fishing season. During the short month of dry-dock time, Cabling & Technology Services (CTS), a full service integrator of network infrastructure systems, removed and replaced the ship’s entire cabling infrastructure.

“It’s very challenging to deploy cabling on a ship due to tight spaces, corrosive sea water and other environmental elements,” says James Gannon, service project manager for CTS. “We needed to deploy connections throughout for Wi-Fi access and to connect to computerized packaging systems in the fish processing area, which is often wet from floor to ceiling and undergoes wash downs as part of the company’s sanitation process.”

Throughout the ship, Siemon Ruggedized MAX IP66/IP67-rated category 6 outlets and modular cords were once again deployed to offer protection against water ingress, as well as the ability to withstand the corrosive nature of sea water that can typically cause non-ruggedized components to fail.

“Trident wanted something that could handle the wet, and Siemon had the product,” says Gannon. “While I’ve used Siemon products for many projects in the past, I had not used their ruggedized connectivity before. We’re also using it in the two other factory trawlers—the Island Enterprise and the Seattle Enterprise—both of which will be completed this year.”

Choosing the Right Partner — From Experience to Breadth of Product

With an increase in the number of harsh environments that are an extension of the corporate LAN, designers and installers who are experienced in commercial environments may not necessarily understand industrial standards, how to use MICE parameters or which product features to look for. Furthermore, standards-based methods and parameters for determining the level of harshness and the components required are not always cut and dry.

While industry standards can be used for determining components based on environment, they often refer to in-between environments as “light industrial.” This term can be confusing when the environment is clearly not one that is industrial but is simply an extension of the commercial LAN into a harsher environment. Consequently, “industrial” standards are not always followed during the planning stages of these environments, often resulting in the use of inadequate components and network failures.

Experience goes a long way in designing for these environments. For example, designers experienced with deploying networks in industrial and harsh environments will likely know that induction heating within about 10 feet of a component can require an E3 classification while fluorescent lighting located a few feet away will have little impact and require only an E1 classification.

Another consideration when selecting ruggedized cable and connectivity is a breadth of copper and fiber types in a variety of performance levels. Most manufacturers of industrial/ruggedized components provide category 6 at best for copper, with many offering only category 5e. Furthermore, few offer the latest fiber cable and connectivity in ruggedized versions. This could very well be due to the fact that many industrial systems don’t require the higher bandwidth associated with category 6A and fiber. However, as more LANs extend into harsher environments, designers are looking to maintain the same performance level as the rest of the corporate LAN. Selecting a manufacturer with ruggedized copper and fiber cable connectivity available in the same copper and fiber performance as the rest of the LAN will prevent connections in more demanding environments from having to compromise on bandwidth and performance.

Commercial designers with limited experience in planning for cable and connectivity that extends into harsh environments would be wise to work closely with cable and connectivity manufacturers who understand the standards and specifications, offer the latest copper and fiber ruggedized components and have experience in determining the type of cable and connectivity required based on a variety of environmental factors.

Rev. A 12/14