Electrical Enclosures

Improving Arc Flash Prevention and Safety

Guest contributor: Steve Sullivan, Rittal

Working among the electrical components in an enclosure comes with inherent risks. The power in any one enclosure can range from 2kw up to 200kw depending on the power density. One of the most common and dangerous risk is an arc flash (or flashover).

When an explosive release of energy erupts from a phase-to-phase or phase-to-ground arc fault the results range from devastating to deadly. This air to ground electrical explosion is a critical concern for engineers and managers who are charged with the safety of their employees.

The Destructive Force of an Arc Flash

The dangers from an arc flash are all too well known. Five to 10 of these accidents occur every day in the United States. When metal expands and vaporizes at the fault, it causes extreme heating of the air, upwards of 10,000°C/18,032°F. The concussive pressure wave can knock personnel off their feet, the ultraviolet light flash can cause blindness, the sound blast, deafness and the molten metal and heat can cause second and third degree burns. The specific death toll has been estimated to be up to 1-2 people per day worldwide.

An arc flash can be the result of unsafe work procedures, accidental contact or more systemic problems such as corrosion of components and connections or insulation failure. Arc flash prevention should be incorporated into any application from the beginning of the design process.

Minimizing Arc Flash Exposure

Design and retrofit approaches can limit exposure by using components installed outside the enclosure to permit qualified personnel in personal protective equipment (PPE) to service equipment inside without opening the enclosure door. Interface flaps and window kits permit data retrieval, equipment monitoring or routine maintenance to be performed from outside. Collapsible fold down shelves be raised for use with laptops and monitoring equipment. External data pockets can hold wiring diagrams, operation manuals and other documents.

Rittal and Arc Flash Protection

Sometimes components must be accessed from inside the enclosure. Rittal’s arc flash solution is designed to keep high and low voltage equipment within the confines of their own respective enclosures. Low voltage enclosures house equipment that is used for programming, data acquisition and system adjustment.

High voltage components are isolated within their own disconnect enclosure, while line side power is segregated within the power isolation enclosure. A partition wall acts as a barrier to high voltage line side power. Rittal’s interlocking door system ensures that the high voltage enclosure cannot be opened while the disconnect switch is in “ON” position.

For additional safety, all interlocked doors and master door must be closed in order to re-energize the enclosure. This removes potential for accidental contact with the inline power when the disconnect enclosure is put in a safe power-off position, and locked and tagged out.

Minimizing exposure to line side power can help protect personnel from accidents. A qualified person wearing PPE and following appropriate safe work practices can perform visual inspections and tasks, such as diagnosis, testing, troubleshooting and voltage measurement with the door open even when the main enclosure is energized.

Rittal offers an unlimited choice of low-voltage and high-voltage enclosure combinations. More important than saving down time caused by having to power down the whole system to service, the Rittal arc flash solution helps to decrease the risk personnel being exposed to arc flash-related injuries.

Safety is always your priority, so download Rittal’s Arc Flash and How to Prevent it whitepaper for the first step towards arc flash prevention.

About Us

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CMA/Flodyne/Hydradyne is an authorized  Rittal distributor in Illinois, Wisconsin, Iowa and Northern Indiana.

In addition to distribution, we design and fabricate complete engineered systems, including hydraulic power units, electrical control panels, pneumatic panels & aluminum framing. Our advanced components and system solutions are found in a wide variety of industrial applications such as wind energy, solar energy, process control and more.

 

The Future of Cooling Technology in Industrial Enclosures

by Eric Corzine, Product Manager, Climate Control at Rittal

As industrial processes scale, the threats and challenges of cooling the racks of automation equipment increase exponentially. Sophisticated, sensitive electronics and drives are the backbone of many industrial systems. This equipment is often placed inside enclosures to protect it from environmental influences such as temperature, moisture and contaminants like corrosive vapors and dust. If these are not prevented, electronic components will inevitably fail, eventually leading to the shut-down of entire production systems. The failure of a production system can add up to losses for an operation.

What will the future look like?
The single most important environmental factor to manage in industrial enclosures is temperature.  Relative to each individual component, the heat of electronic components has increased significantly in recent years. At the same time, the density inside control cabinets has increased dramatically, resulting in a 50 – 60% increase in heat in the enclosures.

With the advent of microelectronics and new electronic components, the requirements for professional enclosure construction and heat dissipation have evolved dramatically over the last few years. Modern enclosure climate control systems must take these challenges into account, offering the best technical solution while guaranteeing optimum energy efficiency. If heat is not managed properly and the maximum permitted operating temperature is exceeded, the service life of these components is halved and the failure rate is doubled.

Trouble-free operation and functioning of production lines is heavily dependent on how the heat generated by electrical and electronic components is dissipated from the enclosure to the ambient environment. We distinguish three different types methods of heat transfer:

  • Thermal radiation
  • Thermal conduction
  • Convection

In the case of enclosures and electronic housings, we are mainly concerned with thermal conduction and convection. With thermal radiation, heat is passed from one body to another in the form of radiation energy, without a medium material, and plays a minor role here.

Whether we are dealing with heat conduction or convection depends on whether the enclosure is open (air permeable) or closed (air-tight). With an open enclosure, the heat (heat loss) can be dissipated from the enclosure by means of air circulation, i.e. thermal conduction, from inside to outside and is typically in a controlled environment such as data centers. However, if the enclosure has to remain closed due to harsher conditions, the heat can only be dissipated via the enclosure walls, i.e. through convection. Depending on the amount of heat loss of the components, these methods may not sufficiently cool the equipment and a climate control product may be required.

Identifying the proper cooling device depends upon the differences between the ambient temperature (Tu) and the desired enclosure internal temperature (Ti).

An additional factor to consider when choosing a means to cooling is the environment in which the enclosure is installed and the ingress protection (IP) rating required.  Each climate product has corresponding IP ratings:

Other innovative, hybrid cooling technologies have been developed that rely upon two parallel cooling circuits working together depending on the temperature differential. An integral heat pipe dissipates heat from the enclosure when the ambient temperature is below the setpoint, providing passive cooling. Active climatization is achieved when the compressor’s cooling circuit is engaged and provides cooling via speed-controlled components for demand-based cooling. Combining the two circuits reduces temperature hysteresis and provides more precise cooling. Not only is energy consumption far less than with conventional technology, but the improved temperature stability leads to longer service life of both the components within the enclosure and the cooling unit itself.

The reliability of electrical and electronic components in an enclosure can be put at risk not only by excessively high temperatures, but also by excessively low ones. The enclosure interior must be heated, particularly to prevent moisture and protect against frost. It is also necessary to prevent condensation within the enclosure. The latest generation of enclosure heaters has been developed with the help of extensive Computational Fluid Dynamics (CFD) analyses. The positioning of the heater is of fundamental importance for even temperature distribution inside the enclosure. Placement of the heater in the floor area of the enclosure is recommended in order to achieve an optimum distribution of temperature and hence efficiency. Thanks to positive temperature coefficient (PTC) technology, power consumption is reduced at the maximum heater surface temperature. Together with a thermostat, this results in demand-oriented, energy-saving heating.

Smarter, intuitive, and more efficient designs will need to be a staple no matter what setting the enclosure is in.  Designers will need to take careful consideration in the initial planning stages of projects, ensuring that the appropriate cooling technology is incorporated into designs.

ABOUT US

cropped-cmafh-logo-with-tagline-caps.png

CMA/Flodyne/Hydradyne is an authorized  Rittal distributor in Illinois, Wisconsin, Iowa and Northern Indiana.

In addition to distribution, we design and fabricate complete engineered systems, including hydraulic power units, electrical control panels, pneumatic panels & aluminum framing. Our advanced components and system solutions are found in a wide variety of industrial applications such as wind energy, solar energy, process control and more.