Introducing the 2024 EC&M 30 Under 30 All Stars

June 23, 2024
Up-and-coming electrical professionals demonstrate innovation in technology as well as commitment to learning and career advancement.

When we started EC&M's Under 30 Electrical All Stars in 2018, we hoped to shine a light on the extent to which young electrical professionals were going above and beyond the call of duty, especially demonstrating innovation, efficiency, and creativity while incorporating technology into their jobs. Six years later, not only has this recognition program massively grown in exposure and popularity, but it also serves as a reminder of the impact the next generation will have on the electrical industry.

Nominations for our 2024 30 Under 30 Electrical All Stars smashed last year's record for number of total submissions. In fact, we received more quality nominations this year than ever before, which is a testament to the incredible young staff working in electrical design firms, electrical contracting companies, and in facility/plant maintenance roles.

This photo gallery showcases the 30 individuals who were selected as 2024’s group of Under 30 EC&M All Stars, and serves as a sneak peek for the full Special Report. Here they are — listed in alphabetical order.

Congratulations to all of the 2024 honorees for everything they have done — and continue to do — to advance the electrical profession.

About the Author

Ellen Parson | Editor-in-Chief - EC&M

Ellen Parson is the Editor-in-Chief for EC&M. She has a journalism degree from the University of Missouri-Columbia. She's been a business-to-business writer and editor for more than 25 years, most of which have been covering the construction and electrical industries. Contact her at [email protected].

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In the typical facility, the plant manager has X amount of discretionary spending power that can be directed toward a single purchase. At each level of management down, discretionary spending is stepped down into smaller amounts. Anything beyond a given manager’s limit must be appealed to the next level up. For example, the Plant Engineer can’t quite swing a purchase of $5200 but the Plant Manager can approve it. This informal arrangement reduces corporate overhead and improves operational efficiency. It does not address whether the spending decisions would make financial sense to the Chief Financial Officer, but the cap at each level keeps any mistakes to a reasonably acceptable loss or misallocation of resources. Beyond the Plant Manager’s limit, there is usually a formal process for getting spending approval. It typically involves filling out a Capital Request (or similarly named form). In well-run companies, the form is very structured. It mostly wants some basic information that will give the reviewer(s) the ability to justify not just the purchase but also the cost of acquiring the capital to do so. Because the funds will typically be borrowed by the corporation, the cost of capital must be balanced against the return on investment. There will be at least one person crunching the numbers to make what is called “the business case” for the proposed spending. Making the business case is something you should do, in some way or another, when considering spending within your approved limits. If the spending is above your approved limits, then the manager above you will need a bit beefier of a business case. The business case must take into account the value obtained versus the money spent. Consider the purchase of a thermographic camera. If you intend to purchase a mid-range camera but nobody at your facility is trained and certified in its use, the purchase is probably a waste of money. You’d be better off getting an entry-level camera and then arranging for a path toward certification if you intend to have that ability in-house and it makes operational and financial sense to do so. And generally, it makes sense to have a person or two with Level I certification so they really understand how to get the most out of a camera system that’s beyond the basic level. On the other hand, if you were a manager at an electrical testing firm with several Level III Thermographers you would be wasting your thermographers if you decided to “save money” by equipping them with only basic or even intermediate camera systems. Your firm needs to be able to troubleshoot problems when that important client calls in a panic. Your thermographers need the tools to do that job, and “cost-saving” on camera systems won’t cut it. Presumably, your clients are smart enough to already have basic camera systems; they just don’t have the expertise to use advanced systems. Sometimes a different logic applies to other types of test equipment. In the typical plant, maintenance electricians need sophisticated DMMs. If they lack the training to use the features that are needed for most effectively keeping equipment running, simply choosing a less capable DMM they already know how to use is not the answer. They need the appropriate DMM along with the training on how to use those features correctly. So far, we haven’t looked at the need to crunch any numbers to make the business case. What we have done is think about the match between the purchase, the problem that needs to be solved, and the ability of the user to solve the problem using that purchase. This sounds like a common sense approach that everyone would naturally take, but people often lose sight of the reason for the purchase in the first place. The tendency is to either go all out on something they can’t use or don’t need, or to “save money” by shortchanging the end users with something that doesn’t allow them to do what they need to do. What about those numbers? When you do a purchase request, a bean counter is going to try to determine the cash flows involved (typically in monthly periods). If you write something like, “The payback period is three years,” they don’t find that helpful. Lenders care that a loan can be serviced, and cash flow is the critical factor in calculating whether it can. Thus, beancounters don’t use payback to determine whether they can afford to borrow. They use the Internal Rate of Return (IRR) or Modified Internal Rate of Return (MIRR). Formulas for both IRR and MIRR have been in spreadsheet programs for over two decades, but before that they were determined using a Business Math Calculator (about $150 in 1990). And before that, they were laboriously calculated by hand. The cash flows that are charted will be either additional revenue generated or losses prevented. To help the person who figuratively wears the green eye shade, tie the use of the test equipment to a revenue stream. A major appliance plant in Tennessee has several production lines that collectively produce $1,560,000 per hour of revenue. Thus each minute of unplanned downtime is quite costly. If the plant electrical engineer there wanted to upgrade test equipment in a way that exceeds the Plant Manager’s spending authority, he needs to help the green eye shade guy do the math. He can cite short case histories from the past two years and briefly explain how having X capability (present in the new equipment, absent in the existing equipment) would have saved Y minutes of downtime (which the green eye shade guy will calculate out in terms of revenue and cash flow). The green eye shade guy also needs to know whether each case history is a one-off that will never recur or if it’s representative of what to expect in the future. You can settle this question with a brief explanation. For example, “The responding technician did not have a [name of test equipment]. Consequently, he had to arrive at the same conclusion by other means to the tune of 24 minutes of downtime he would not have incurred if he’d had a [name of test equipment]. This problem occurred once on Line 2 and twice on Line 4.” Now the green eye shade guy can simply add up the downtime, monetize it, and create the cash flow analysis. And it’s really good for something like a power monitor. For example, “In this particular case the plant did not have a monitoring system capable of detecting short-term bursts of power, which we call transient spikes, and alerting us. Transients happen with no notice, and usually without being detected. The motor shop forensic report shows the main motor failed due to winding insulation failure caused by transients. With a power monitor detecting and reporting those transients, we would have been able to intervene before outright failure, on a scheduled basis. That would have reduced downtime by 57 minutes twice last year alone.” Making the business case for your smaller purchases means simply thinking about what you are trying to accomplish and then making sure you are spending the funds correctly to achieve that goal. But as you go up the food chain, you need to make the picture more clear. And when you appeal to corporate for approval, you need to provide reasonably accurate downtime savings numbers that can be converted by them to revenue loss prevention in specific dollar amounts.
Man staring at wall with hand-drawn question marks and money bags on it

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