Is Your Fabricator All That? Three Keys for Measuring Value.

Is Your Fabricator All That? Three Keys for Measuring Value.

At Crow, one of our goals is to be the first-place mills turn to improve their operations. Traditionally, we’ve pursued this goal by providing capital and maintenance project support services. Now – after acquiring Automation Industries Corporation (AIC), now Miloptic – we’ve added custom metal fabrication to our portfolio of offerings. Custom fabrication is an art – one that requires more than machines and technology for bending, forming, and cutting. Thus, as part of this acquisition, we were particularly pleased to incorporate many talented people with years of fabrication skills into the fold at Crow.

If you are looking for a metal fabricator, you might want to learn from our own acquisition experience. Here are three key points to consider to make sure your fabricator can deliver the value you expect.  

1. Equipment and materials

Does your fabricator have top-of-the-line equipment such as welders, millers, and CNC machines? And do they utilize the highest quality materials and alloys?

As a metal fabricator, it is important to supply precision metal products, heavy structural steel and plate fabrication, and sheet metal. A good fabricator offers services such as cutting, fitting, welding, testing, finishing, painting, and assembly.

 

2. Engineering skills

Does your fabricator have skilled engineers that pay attention to details and ensure that the equipment and parts are made specifically for your application?

Offering added services such as engineering and custom design to the fabrication is a plus. Make sure the fabricator has designers who work from any standard engineering drawings or plans and provide industrial design services.

3. Installation and turn-around

Can your fabricator install and deliver with a short turnaround?

If a project requires both fabrication and field installation, choose a fabricator that has the capabilities to tackle many types of projects as well as emergency repairs, training, and calibration. Also, keep in mind that choosing a fabrication shop that is centrally located will allow you to have more control of your products and lead time.

If you need conveyor modifications, hoists, catwalks, platforms, safety upgrades, and other fabrications for your expansion plans, be sure to tap the kind of expertise that can help you avoid mistakes, minimize costs, and ensure success.

Give us a call (503-213-2013) or email us (inforequest@crowengineering.com) to schedule a consultation and understand your fabrication needs.

Improving productivity with PLC programming

Improving productivity with PLC programming

If you need to upgrade or improve your PLC systems, start by collecting detailed field notes of equipment, wiring, functions, etc. This will give you a detailed list of components that need to be supported by your PLC systems as well as catalog of necessary parts such as new control processors, modules, remote racks, motion control components, network switches, console components, and more. Another essential task to do before the configuration of an automated control system is PLC programming.
Read more about how your operation can improve productivity with PLC programming

 

Improving productivity with PLC programming

In simple terms, a Programmable Logic Controller (PLC) is a robust computer with a microprocessor – but without a keyboard, mouse, or monitor. It is used to control industrial equipment and monitor condition states regarding temperature, moisture, dust, and more.

A PLC uses protocols and ports to communicate with other systems. After receiving information from connected input devices and sensors, the PLC processes the data and triggers required outputs per pre-programmed parameters. Based on these inputs and outputs, the PLC monitors and records runtime data regarding machine productivity, temperature, and other parameters. It can also generate alarms when machine failure occurs and initiate automatic start and stop processes – just to name a few capabilities.

To interact with a PLC, users require a Human Machine Interface (HMI). These can take the form of touchscreen panels or simple displays that allow users to input and review PLC information in real time.

When Crow works with clients seeking to improve or upgrade their PLC systems, the first activity we propose is to conduct a PLC assessment to collect detailed field notes for equipment, wiring, functions, etc. The result of such an assessment is a detailed list of components to be supported by the new PLC system – along with a list of necessary parts such as new control processors, modules, remote racks, motion control components, network switches, console components, and more.

The critical importance of programming

Another essential task is PLC programming. A PLC program consists of a set of instructions, which represent the logic to be implemented for specific industrial projects and applications. At Crow, our PLC specialist and skilled industrial electricians provide essential programming services for new PLC, HMI, and motion control systems. We study existing programs to replicate functionality, write new logic based on existing systems, and design new HMI applications to replace existing implementations.

Proper PLC programming is essential for making equipment and operations faster, more efficient, and more cost-effective. Program functions include initiating the conditions for starting a specified task, executing interruptions, and handling errors. When programmed correctly, PLCs play a critical role in enabling automation, minimizing power consumption, increasing system control, keeping records, and redistributing the available workforce to increase productivity.

Our PLC specialists also have the skills and assistance of our engineering group at their disposal. They can quickly order up needed drawings (layout drawings, control power drawings, or I/O drawings to detail device connections to new PLC) or request project management to ensure vendors and contractors are on track and deadlines are met. We also have the resources to commission equipment – and we always stick around to train technicians and operators on how to get the most out of the new system.

Why a PLC upgrade?

If you deal with reoccurring equipment nuisance issues daily, there’s a good chance these can be resolved through minor changes in your PLC Logic. Your personnel may consider these nuisances to be a simple fact of life – but with some critical observations and the right information, Crow can help you illuminate the underlying cause standing in the way of improved productivity and operational efficiency.  

Let’s say you have a minor issue that causes your line to stop five times a day with a loss of two minutes each stop. Maybe this seems like something you can live with – but, assuming a seven-day operation, you’d lose 60 hours of production per year. When your PLC is not working properly or is down, your machines stop running – causing delays that reduce productivity and cut into revenues. Crow can help. Call (503-213-2013) or email Crow (inforequest@crowengineering.com) to schedule a consultation. Our PLC specialists can provide an assessment, programming, and recommendations to improve your process.

Many investments and upgrade projects continue to emerge in the US South

Many investments and upgrade projects continue to emerge in the US South

As home construction grows, lumber consumption in the US and Canada will increase from 59 billion board feet (BBF) in 2020 to 70 BBF by 2025. Anticipating increased demand and seeking to capitalize on an extraordinary surge in lumber prices above $1,000 MBF in 2021, lumber manufacturers are making significant investments to expand manufacturing capacity. The US South – the largest softwood lumber producing region in North America (20 BBF) – is seeing most of the investment. Simultaneously, smaller lumber producers and much larger corporations will exceed 4 BBF of softwood capacity by 2022 due to many mill modernizations, reopenings, and greenfield projects to increase production capacity. The following are the recent major investment announcements:

  • Interfor
    March 2021, Interfor acquired WestRock’s sawmill in Summerville, SC (125 MMBF) for $59 MM (included log and lumber inventories). Interfor will invest $30 MM to increase production up to 200 MMBF annually. Also, in July 2021, Interfor purchased three sawmills from Georgia Pacific in the US South: DeQuincy, LA (200 MMBF) to be restarted in the first half 2022, Bay Springs, MS (140 MMBF), and Fayette, AL (160 MMBF). The acquisition of these three sawmills plus a sawmill in Philomath, OR were cash purchases for $372 MM (including working capital). Interfor plans to invest up to $8 million to revive the DeQuincy sawmill curtailed by Georgia Pacific in May 2020.
  • Hunt Forest Products and Tolko Industries
    In July 2021, Hunt Forest Products and Tolko Industries announced a project to build a 320 MMBF sawmill in Taylor, Louisiana ($240 MM). Construction of the new facility is expected to start in early 2022, with commercial operations starting in early 2023.
  • Roseburg and Canfor US South
    Also in July, Roseburg announced a $200 MM investment to build a 400 MMBF sawmill in Weldon, NC., and Canfor US South announced a 250 MMBF greenfield sawmill near DeRidder, Louisiana ($160 MM) with startup projected in late 2022. Since 2013, Canfor US South has had over 300% growth.
  • Georgia-Pacific
    September 2021, Georgia-Pacific announced the modernization of its lumber complex in Pineland, Texas with a $120 million investment. Construction is expected to begin early 2022 and is scheduled to be completed in late 2022. Currently the mill has the capacity to produce 380 MBF of dimensional lumber each year, but when the new mill is operational and running at full capacity the production will increase to 450 MBF.
  • West Fraser
    October 2021, West Fraser entered into an agreement to acquire Angelina Forest Products lumber mill located in Lufkin, Texas for approximately $300 million (financed with cash on hand). This sawmill began construction in 2018, commenced operations in late 2019, and is expected to progress toward full production capacity of approximately 305 MBF over the next three to four years.

The industry knows that the US needs to add about 1.5 million new homes per year to keep pace with population growth and replace existing homes. Forecasters indicate that lumber capacity in North America will fall short of new demand by close to 7 BBF which is equivalent to more than 20 large-capacity sawmills. At Crow Engineering we are currently involved in many mill assessments, modernizations, and capacity expansion projects. With more than 50 years of experience, it is Crow’s  honor and privilege to serve mills and lumber companies. Contact us if your company is planning to take advantage of the current market. We would love to help you make the right decision and achieve your goals.

The time is now for a structural assessment

The time is now for a structural assessment

To ensure safety and minimize the risk of operational shutdowns at a time of high demand, many mills commission a structural assessment of critical facilities. Such assessments typically involve an analysis and evaluation of foundations, framings, and associated construction systems and details. The objective is to determine existing load capacity, identify structural deficiencies, and assess the causes and impacts of potential structural failures.

The extent of such an assessment depends on the condition and complexity of the resource examined, its current or intended use, and the amount of information available or attainable. But whatever the particular circumstances, mills want clear recommendations to correct structural deficiencies – or a new structural design with specific engineering solutions.

Expertise needed

It’s important to investigate thoroughly and know what you’re looking for. For example, in a recent review for one customer, a Crow engineer investigated the performance and construction of bowstring trusses. What initially appeared to be a tension (bottom) chord failure was actually a symptom of a more serious issue: the failure of the compression (top) chord. READ MORE

Essentially, the top chord was compromised and shortened. This caused the more noticeable failure of the bottom chord.

Using an animation, our engineer, simulated on-site conditions and showed what would happen to the truss if the compression chord failed. The animation made it clear that as the compression chord failed, it shortened – causing the tension chord failure. While applying a tension chord splint would alleviate the secondary failure (bottom chord), it would also increase load to the compression chord and exacerbate the primary failure mechanism.

To ensure the safety of this truss chordcompression (top) chord needed to be supported. Critically, it was determined that supporting the truss through the bottom chord only (and only on one side of the shoring tower) would have increased the load in the web members, causing the failure of web members,  shear plates, and strap plates. These conclusions led our engineer to recommend a shoring design to be put in place as soon as possible.

The three levels of a structural assessment

Structural assessments vary. Generally speaking, there are three varieties:  

  • Cursory Assessment
    Visual overview of the general condition of the building envelope. It is often used for screening multiple buildings to establish priorities for maintenance and repair or further study.
  • Preliminary Assessment
    Site visit to identify problem areas, review available documents, interview of involved parties, and generate a preliminary report of findings and recommendations.
  • Detailed Assessment
    Review of documentation, component classification, field investigation, testing, analysis, and report.

Each assessment should be supplemented with a structural assessment report. Such a report looks at working conditions and makes recommendations for immediate and short-term repairs – all based on visual observation, measuring, video/photography, sampling, testing, analysis, and documentation depending on the level of the assessment.

Faulty construction, unsafe structural conditions for gravity and wind/snow loads, substantial structural damage due to deterioration – all of these can be identified with a structural assessment. Addressing these issues can help prevent further facility damage, collapse, equipment loss or damage, and – most importantly – accidents and fatalities.

Do you have structural questions? Call (503) 213-2013 or email Crow info@crowengineering.com to schedule a consultation. Our registered Professional Engineers (PE) can provide a structural assessment and report to evaluate your structural conditions and needs.

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Can’t Fill Your Manufacturing Jobs? Read This Before It’s too Late: 3 Keys to Attracting and Keeping Manufacturing Employees

Can’t Fill Your Manufacturing Jobs? Read This Before It’s too Late: 3 Keys to Attracting and Keeping Manufacturing Employees

It would be difficult to argue that American manufacturing is in a slump. In March 2021, activity in the sector surged to a 37-year high.

Yet at the same time, an estimated half million jobs in manufacturing remain unfilled. Across the spectrum – from low-skilled entry-level positions to specialized roles such as welders and machinists — factory operators find it increasingly difficult to find the workers they need.

According to a study published by Deloitte and The Manufacturing Institute, as many as 2.1 million manufacturing jobs will be unfilled through 2030. At the same time, approximately 2.7 million workers are expected to retire over the coming decade while business growth will result in the need for 700,000 new jobs.

Manufacturing executives cite two main reasons for the current predicament. The first is obvious enough: there simply aren’t enough workers with the skills and training needed for modern manufacturing.

The second reason has more to do with the expectations of today’s American workforce. Younger workers, for instance, reject factory jobs as stationary, low-knowledge work with few prospects for advancement. Many believe manufacturing jobs are obsolete and will be replaced by robots and overseas competition. Other options – such as technical or professional pathways in other industries – seem more attractive. And, of course, there’s always the side hustle alternative. Increasingly, workers can find flexible and fulfilling work through options such as Uber, social media, freelancing, and more.

Adding to the mix is the phenomenon of the great job migration, where many employees are reevaluating their work and leaving their current employers to find more desirable jobs elsewhere. If your company is facing these headwinds, consider the following tips for attracting and keeping valued manufacturing employees.

Show them the money
Many manufacturing positions require fairly basic capabilities – such as following directions, willingness to learn, and follow-through. Think of positions such as assemblers, production work helpers, and hand-held tool cutters.

Traditionally, these jobs may have been categorized as entry-level and minimum wage. Things have changed. Today’s factories compete with entry-level talent from warehouses and distribution centers run by the likes of Amazon, Costco, and Walmart who pay $15 per hour or more. To keep pace, factory employers are aggressively boosting pay to attract the best employees.

Manufacturers also are increasing the shift differential paid for work on second and third shifts – the jobs often assigned to new hires out of respect for the preferences of more tenured employees. Higher second and third shift pay rates can aid recruitment, without increasing labor costs on the traditionally coveted first shift. FedEx Express, for example, is adding $2 per hour to the wages of night operations employees at its World Hub in Memphis, Tennessee. 

Bring sexy back
If manufacturing jobs seem unattractive for today’s workers, maybe it’s time to bring sexy back. To attract employees, many companies are initiating sign-on bonuses after the successful completion of a probationary period (typically 60-90 days). Others are adding or increasing bonuses paid to current employees who refer successful job candidates.

Schedule flexibility is attractive to new hires as well. Some companies offer flex schedules where fulltime may not be a requirement and the ability to move between shifts is facilitated. Others offer flexible vacation schedules so that employees can take a day off here and there to take advantage of the good things in life – like the beginning of hunting season, a child’s school event, or maybe the chance to go to a ball game on short notice.

To keep employees motivated (especially younger workers with the right skill sets), smart manufacturers are also investing in worker training and focusing on career growth. During the hiring process, these companies set realistic career expectations for new employees – with clear roadmaps and timelines regarding pay raises, promotions, and training opportunities.

When it comes to attracting and retaining good and loyal employees, the role of company culture should not be overlooked. Companies can minimize turnover and show that they care about their employees with straightforward measures such as maintaining a comfortable, clean, and safe environment. If employees are still quitting, managers need to initiate open up the lines of communication. Managers who encourage input and feedback aren’t just building stronger teams, they’re building strong company cultures.

Personal touches count too. Celebrate team milestones, host a quarterly barbeque, provide positive feedback, and encourage creativity. Foster respect, encourage a healthy work-life balance, connect with team members, and provide the tools they need to succeed. “Little things” like these can play a big role when it comes to keeping employees happy and productive.

Know where your workforce is coming from
Many manufacturers are implementing strategies that target specific populations with a tailored recruiting approach. Some pursue military veterans, others help to enroll students at nearby trade schools and community colleges. Trade associations are also helping their members by establishing relationships with schools and workforce organizations.

Historically, companies have required a basic grasp of the English language. Today – particularly amid the COVID-19 pandemic – many companies have dropped this requirement, thus widening the available pool of potential workers. To attract Spanish-speaking workers, for example, some companies are placing Spanish-language billboards throughout their cities and are sponsoring events such as Hispanic Festivals to speak about employment opportunities.

Finally, to rebuild the employee pipeline, many manufacturers are revamping their hiring requirements across a range of areas. Traditional requirements – such as marijuana screenings and drug tests, disqualifying convictions, high school diplomas, and prior experience – are now being deemphasized or eliminated entirely.

You can’t control everything, but you can be proactive
In normal times, people quitting jobs in large numbers is a sign of a healthy economy with plentiful jobs. But these are not normal times. The pandemic has led to a massive recession here in the U.S. Millions of people are still out of jobs. Yet, employers now face severe labor shortages – even as pandemic life recedes.
The younger generation is leaving jobs in search of more money, flexibility, and happiness. Many are rethinking what work means to them, how they are valued, and how they spend their time. Rather than clock in at the same company for 40 years, today’s workers are more willing to switch jobs frequently if it means getting the income they need and a schedule they want. And if their current position won’t let them pay down debt or fully support their lifestyle, today’s workers now have the means to add a side hustle to earn extra money.

Ultimately, there is no way you can control every aspect of your team’s work experience. If someone wants to leave, there is little you can do. That said, proactive measures as described here can do wonders to keep employees happy in the first place – while improving the performance and cohesiveness of your workforce. The result is increased employee satisfaction and loyalty.

At Crow, we’re here to help you in such efforts. We can provide operational and maintenance training to support your employees and management team. We can also help with training to your Spanish-speaking personnel. Need a hand? Give us a call and learn more about how Crow can help: (503) 213-2013. 

 

Why Is My Blow Detector Inconsistent?

Why Is My Blow Detector Inconsistent?

Other Blow Detectors Can’t Meet Performance Standards. The Reasons Are Clear.

There are two primary problems with ceramic crystal transducers used in blow detectors. The first is that they’re finely tuned devices (with a high Q factor) where the transmitter and receiver need to operate within in an exceptionally narrow frequency band. These devices tend to drift – and not necessarily together. Because of the narrow frequency requirement, a small amount of drift can have a dramatic impact on received energy. This causes the detector to trip on false positives – an expensive proposition for a plant.

The second problem has to do with resonant frequencies and broadband applications. A typical transducer includes a transmitter and receiver. A standard Miloptic transmitter produces a narrow band output targeted at frequencies in the 16-95khz range. The receiver – which is broadband over this range – is electronically narrow-banded later in the process. This allows the system to be tuned to a “sweet frequency” – one that is ¼ or ¾ wavelength in the material being inspected. At ¼ wavelength, or a multiple thereof, the material approaches transparency – making it much easier to penetrate. However, piezoelectric ceramic crystals do not like to be driven off their resonant frequency – and, therefore, are not effective in broadband applications.

I have encountered both of these problems based on decades of hand-on experience. In 1968, I worked with my team at Trienco – now Miloptic – to build and install the world’s first air-coupled blow detector. Initially it worked great – but when it was installed into a high-production mill, we started to see issues.

The ceramic crystal transducers in the initial design drifted – causing inaccurate positive readings. Our testing at the time showed that blow detectors with ceramic crystals will never deliver consistent results under high-production conditions. It took some time, but by mid-1973 we successfully developed our exclusive transducers without ceramic crystals. The Trienco 506 system was born.

Since then, we have successfully installed over 220 Trienco 506’s. We are extremely proud to report that many of them are still in service – after 30 years of operation. As technology improved and our engineering expertise has increased, we launched the 5600 and current 5700 product lines. The new 5700 series has been designed to integrate with Rockwell and other PLC solutions. It also provides solutions for many different panel types – in addition to flooring, gypsum, and siding. And best of all, Miloptic’s products are made in the USA.

Want to learn more about the differences between the Miloptic transducers and their ceramic counterparts used by most of our competitors? Feel free to call us at 503-213-2013 or email us at support@miloptic.com.

Looking to Upgrade a Conveyor? Ask These Questions First

Looking to Upgrade a Conveyor? Ask These Questions First

When it comes to upgrading conveyors, it’s important to move deliberately. For starters, you’ll need to assess the space, infrastructure, and equipment in place. Because a conveyor expansion or modification represents a substantial capital investment, you’ll also want to carefully analyze all available options. You need to weigh benefits against costs and assess your tolerance for risk.

At Crow, we are continuously involved in projects to help customers achieve and exceed their expansion goals. In our experience, when designing conveyor layouts, it’s important to consider the following during the conveyor design process. Going through these simple considerations can greatly reduce design mistakes and help you avoid costly operational downtime in the future.

  • Material
    What is being conveyed? What is the product size, composition, flowability? How will the material behave as it is being handled or processed? These questions help you figure out the best type of conveyor and chain to choose for the uses you have in mind.
  • Operation
    Here, we consider operational requirements around function and performance. A key metric is the amount of material you intend to convey in a specified timeframe. Knowing the demand for such material at each process or operation point will guide your decision-making from the start. Also consider hours of operation. How often do you expect the conveyor to run?
  • Environment
    Every conveyor runs in some type of environment. What is your environment like? Can it withstand the rigors of relevant environmental extremes – such as temperature, humidity, corrosion, vibration, etc.? Another important question: Are their open sources of ignition? Will the environment be flammable or explosive? Answers to these questions might lead you to consider explosion-proof motors, corrosion-resistant bearings and shafts, or other design choices.
  • Footprint of conveying system
    Your conveyor needs to fit in the space allotted. When designing new or modified conveyor equipment, particularly when some portions of the system already exist, important considerations include infeed/discharge elevations, centerlines, and the operational speeds of existing machines that work with the conveyor. Also, is anything in the way? Do you have to avoid columns, ceilings, walkways, mezzanines, material staging areas, or pedestrian or forklift traffic?
  • Maintenance
    How easy will it be to perform regular preventive maintenance? Can you quickly swap out chains, bearings, motors, belts, shafts, sprockets, etc.? These are important design considerations with an obvious goal – to maximize maintenance efficiency and minimize the potential for costly downtime that comes with machine failure.
  • Conveyor components
    Is your conveyor designed with components that are easily sourced? Can they handle the environment? Are they available from local distributors? Are they cost effective? The last thing you want is for operations to come to halt for want of an essential part that’s difficult to find.
  • Safety
    Does your conveyor design follow applicable OSHA requirements and local laws? Does it have proper guarding at pinch points or known hazardous areas? If pinch points/hazards cannot be guarded, could you fence off the conveyor or system to restrict access and potential accidents?
  • History
    Be sure to listen to the experts. They’ll provide insight into what has and hasn’t worked in the past. When replacing existing equipment, the importance of functionality, reliability, and service history should not be overlooked. At the same time, your own history is critical. If conveyor reliability or functionality has been an issue for you in the past, understanding these issues can lead to suitable design changes and countermeasures. The result is more satisfactory results for your material flow goals.

Trust in Crow

By considering the questions discussed here – and by remaining in constant communication with the customer – Crow has helped many customers achieve their conveyor design goals. We provide full design or on-call engineering for small and fast-track projects that need to be handled quickly with a minimum of expense. We manage the initial design and can also support the project throughout construction.

If you have conveyor modification, upgrades, and expansion plans, be sure to tap the kind of expertise that can help you avoid mistakes, minimize costs, and ensure success. Give Crow a ring at (503) 213-2013. We’d be happy to talk. 

 

 

Why Plant Modernization? Four Reasons to Go with a Brownfield Expert

Why Plant Modernization? Four Reasons to Go with a Brownfield Expert

Structures and equipment don’t last forever. At some point, they begin to exhibit signs of wear and tear. Eventually, you need to take action.

The enemy is procrastination. Last minute repairs are costly – particularly when equipment has already failed and production has come to a halt.

Neither do you necessarily want to rip and replace. New equipment is nice – but a simple cost-benefit analysis often shows that keeping existing equipment up and running (perhaps with modifications) makes the best financial and business sense.      

Which is what ‘brownfield” plant modernization is all about. There’s a lot of value in the equipment you already have – and with plant modernization, you can keep on generating value for years to come.

Let’s take a look at four reasons for moving forward:

Safety

When a worker becomes sick or injured, the business feels the effect. But potential safety risks can be anywhere – in degraded equipment or outdated building structures; in ventilation, electrical, and waste management systems; or even in manufacturing production processes.

A plant modernization initiative can focus on the present and future conditions of equipment, buildings, and manufacturing processes to help minimize safety risks. You can also assess when to replace, upgrade, and expand operations before it is too late. Modernization can be a big step forward when it comes to ensuring workers are operating in safer conditions.

Cost Savings

One big advantage of plant modernization is the financial savings – and these can be realized surprisingly fast. When scheduling and executing retrofits, upgrades, and expansions, it is important to consider downtime, mill flow, operating budget, and other factors. The goal is to maintain what’s working correctly, extend the life of existing equipment, and modify only what will provide ROI with minimum risk.

Direct replacement is an option – but when modernizing a process or a facility, a holistic, creative, and innovative approach that integrates old and new in an existing environment can pay far higher dividends. All different options should be examined and considered before starting demolition and pouring concrete.

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Reliability

To serve customers consistently and maintain manufacturing productivity, having reliable systems in place is a must. Equipment lifespans of 30 years or more are common, and many facilities maintain operations for 40 to 60 years. Up-to-date equipment improves overall reliability by eliminating the faults that may occur as equipment ages. Unplanned power outages, costing thousands or millions of dollars, can be avoided with a well-designed upgrade plan that minimizes downtime to just a few hours or less.

Digital Capabilities

As technology continues to develop and improve, plants can benefit from integrating modernized equipment that facilitates cloud and Internet of Things (IoT) connectivity. Many digital components of electrical equipment tie directly into enhancing facility management – enabling plant managers to make smarter decisions. The result is actionable insights for managing and maintaining critical systems and avoiding unplanned downtime.

Getting Started

Plant modernization starts with a functional assessment to address issues in a quantitative way that considers business investment and ROI. Sometimes, such an assessment simply reaffirms your intuition about what is best for the facility from both physical and financial perspectives. Other times, it can uncover hidden issues you may not have seriously considered beforehand.

During this assessment, it is important to review existing building plans for the facility. If contemplating an addition, you may require a site survey. It is also important to gather and generate documents related to the age of the building. This documentation can be useful when it comes to resolving any environmental or code issues and evaluating existing mechanical systems.

For more than 50 years, Crow has provided plant modernization design services to help our customers avoid the costs associated with last minute upgrades and unplanned downtime. During a plant modernization project, we assist clients through the estimation, design, and construction phases. Design input is taken from plant, project, and maintenance managers, and floor personnel. Together we hold team meetings with all stakeholders across the organization and act as the primary point of contact for manufacturers, designers, engineers, and vendors. We are very flexible and can manage any and every individual task throughout the project.

Take, for instance, a recent sawmill modernization project that Crow helped to manage. By going brownfield – repurposing the current facility at the mill – the customer saved half a million dollars in capital expenses. This savings allowed us to significantly increase the roof capacity, add a bridge crane system that was more than 2.5x the capacity of the current system, and increase the span and reach of the crane system. In parallel, we engineered the support systems needed to fit all new saw equipment into the new space. Crow achieved 5% accuracy in project estimation costs. More importantly, the customer was able to get more value from its modernization effort – thanks to a brownfield approach that helps deliver better ROI.

 

Call 503-213-2013 or email us at inforequest@crowengineering.com to assess your modernization goals

Specification and Design of Pre-engineered Metal Buildings (Part II)

Specification and Design of Pre-engineered Metal Buildings (Part II)

by Brett W. King, PE, SE;
Structural Engineering Department Manager

In the first part of this article, we looked at the basics and dimensions of metal buildings for industrial settings. In this second part of the article, we explain the design criteria and specifications of pre-engineered metal buildings.

Design Criteria and Specifications

Design criteria are commonly specified by the building buyer to meet their specific needs. Specifications for buildings are usually a combination of drawings and written documents that provide the information needed by the metal building manufacturer. These documents can be used to get multiple bids for a building or to contract with a preferred vendor.

In some cases, a building buyer may frequently purchase metal buildings – with purchasing decisions often based on a very limited set of specifications. This may happen after a vendor has provided a number of buildings to a particular buyer and an understanding has been developed for just what the customer wants and what the vendor should deliver.

In other cases, organizations such as the Metal Building Manufacturers Association (MBMA) provide model specifications that can be used to order buildings with ordinary common specifications created by the MBNA. These specifications cover the most common criteria for siding and roofing material, design codes and structural loading, coatings, and more.

Building Layout and Finishes

It may be possible to specify simple buildings in text format via written specifications. However, it is usually more effective to prepare drawings that show the layout and dimensions of the building needed. This requires that the buyer to prepare drawings themselves or hire the services of an engineer or architect.

The advantage to this approach is that the building layout can be thought through carefully. Building dimensions, door and window sizes and locations, structural loading requirements, material types and colors, and much more can all be specified in advance. Issues such as inside clearances, eave height, and building width can all be worked out in detail prior to engaging bidders who may be interested in winning the project.

This effort is most critical when there are tight limit or requirements for inside clear height – for instance, to enclose equipment or to provide for the support of cranes.

Standard metal buildings will be delivered typically with a shop-applied coat of primer only. During development of the specifications, prior to bidding, is the time to determine if more appropriate and capable coatings are required. For buildings that may be subject to high humidity or corrosive materials, as may be the case for many industrial environments, special coatings should be considered. Frequently, these will not be provided by the manufacturer of the building but will be applied to the building after erection. It is important, though, to specify the proper primer for the coating intended for use after erection. The building manufacturer must be required to use any specified primers and include the product in their bid. 

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Building Loading

Pre-engineered metal buildings must meet the requirements of the building code of the jurisdiction where the building will be built. Most of the loading criteria will be the minimum loads specified by ASCE 7 Minimum Design Loads for Buildings and Other Structures. This building code specifies all of the required environmental loading for wind, earthquake, and snow that will occur at the site.

The gravity loads, or dead load weight of a building, are calculated directly from the dimensions of all components including rafters, purlins, insulation, and metal roofing. It is common to add an artificial superimposed dead load of 5 pounds per square foot (psf) to the design of roof purlins and rafters. This load is intended to accommodate additional weight of items such as lighting, sprinkler systems, and HVAC duct work of an ordinary nature. It should be noted that some manufacturers may use only 3 psf for this purpose. This will reduce costs but limits allowable loading by the building owner and is not usually recommended by specifying engineers.

Where a building buyer has special needs, additional loads must be clearly specified for the building manufacturer to consider while bidding and for design. Some examples of special loads that must be specified include cranes, hanging mechanical equipment, roof top supported equipment, and just about anything else that may exceed a 3 to 5 psf superimposed load. In some cases, it is helpful to simply specify a superimposed load that’s higher than 5 psf in order to provide a more robust oof structure.

Summary

In summary, this article provides a limited view into the design and specification of pre-engineered metal buildings. Please contact us to achieve the best results and receive a building that closely meets your needs. Crow can help you to develop drawings and written specifications that you can use to submit bids that meet your space, clearance, and load requirements.

Specification and Design of Pre-engineered Metal Buildings (Part I)

Specification and Design of Pre-engineered Metal Buildings (Part I)

Pre-engineered metal buildings are common features in industrial settings. In fact, they have become common features in many types of construction from utilitarian sheds to keep out the elements to multi-story architectural buildings for just about any use. This is the first part of an article looking at specifying metal buildings for industrial settings.

Figure 1. Common Metal Building Components (image found on internet, creator unknown)]

The Basics

Pre-engineered metal buildings are metal building systems that have been commonly called pre-engineered. They go by a few common acronyms such as MBS (metal building systems), and PMB or PEMB (pre-engineered metal building). The term pre-engineered primarily grew from the idea that these metal building systems were designed and engineered for a set of pre-defined sizes and loadings prior to any customer order. These buildings can be quickly ordered, delivered, and erected on the customer’s site without the need for custom engineering. In a sense, these buildings might be considered kits. To fill an order, materials are pulled from common stock and delivered to the buyer. The building is then erected by a separate contractor.

Standard size metal building kits can be ordered from many supplier catalogs – with options for doors, windows, color, and more. One can find these kits advertised online or in magazines for use as small sheds or outbuildings. However, some engineering or customization may still be needed to accommodate certain site conditions such as wind speeds, earthquakes, or snow loads.

Most metal buildings ordered for industrial use require some form of additional special requirements such as customer-specified dimensions and design loads, and features such as cranes. For buildings in this category, building engineering and calculations are actually done after the building is ordered, and final structural sizes are not known until this effort by the vendor is complete.

Figure 2. Typical Metal Building Cross Section

Vertical Dimensions

It is common to specify the building width and eave height as shown in Figure 2. These dimensions set the outer limits and height of the building in a way commonly used by metal building manufacturers. The eave height is usually specified to the top of the roof purlin. An 8-inch purlin, placed on top of the rafter, is commonly used – although deeper elements can be selected based on the roof loading and deflection limits desired. Specifying the outer dimensions in this way allows the outer overall building size to be controlled, which is usually desired.

At the time of ordering, the clear height on the inside of the building may not be known since the final depth of the purlins and the rafter is based on the final calculations for the member sizes. This can pose a problem in some situations where large rafters drop a significant distance into the space inside. For example, it may be necessary to maintain a minimum clearance for storage racks or a piece of equipment inside the building. Mobile cranes are another item that requires minimum clearance to the lowest portion of the horizontal rafter.

In these situations, the required inside clear height of the building can be specified instead of the eave height in order to ensure the required clearance. In this situation, the eave height will vary based on the final determination of the rafter depth. Where there are building site limitations for both the minimum internal clear height and the maximum eave height (matching an existing building, for example), it may be necessary to contact a building vendor to ensure that the allowable rafter dimension can be achieved.

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Horizontal Dimensions

The overall outside dimension of the building to the outside face of the horizontal wall girts is usually specified in order to control the overall size of the building similar to specifying the eave height. Wall girts are most commonly placed on the outside of the vertical column face as shown in Figure 2 at column line B. This allows for easier connection detailing to the face of the column and allows the girts to be overlapped creating a stiffer wall and allowing for a larger girt spacing.

Girts may be inset as shown at column line A in order to accommodate needs such as minimizing the overall outside dimension while minimizing intrusion of the column into the interior space. This option is usually more expensive for the steel building manufacturer although it has some benefits that can be considered. Where inside horizontal clearance is needed, but the building’s outside dimension is restricted, insetting the column into the girt space can make for a bit of extra width.

While wall girt size can vary, an 8-inch wide girt is common. Similar consideration may be needed regarding the horizontal clear space inside the building versus the overall outside dimension specified. This is because the wall girt can vary and more commonly the column dimension may not be known until after the building is ordered.

In many cases, it will be necessary to work with a metal building manufacturer prior to ordering to determine if the required dimensions can be achieved.

In the next newsletter we will describe the design criteria and specifications of the pre-engineered metal buildings. If you have any questions regarding this topic or need structural engineering, please contact our office to understand how we can help.

 

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