Building Codes

History of Building Codes

Building Codes go back to approximately 1772 BC, when the Babylonian emperor, Hammurabi, enacted Building Codesthe Code of Hammurabi. Incidentally, here are those codes – or laws – that pertain to construction:

  • 229 – If a builder builds a house for someone, and does not construct it properly, and the house falls in and kills its owner, then that builder shall be put to death.
  • 230 – If it kills the son of the owner, the son of that builder shall be put to death.
  • 231 – If it kills a slave of the owner, then he shall pay, slave for slave, to the owner of the house.
  • 232 – If it ruins goods, he shall make compensation for those goods, and inasmuch as he did not construct properly this house which he built and it fell, he shall re-erect the house from his own means.
  • 233 – If a builder builds a house for someone, even though it is not yet complete; if then the walls seem toppling, the builder must make the walls solid from his own means.

Steps in Unifying the Codes

In the early 1700’s AD, George Washington and Thomas Jefferson pushed for the development of Building Codes to provide minimum building standards for the health and safety of citizens. Then, in the early 1900’s, Insurance Companies, in an effort to reduce property loss claims from improper construction, lobbied for further development of codes.

The Building Officials and Code Administration (BOCA) was established in 1915 and developed the BOCA National Building Code (BOCA/NBC). Primarily, this code was used and enforced in the Northeastern United States. The International Conference of Building Officials (ICBO), established in 1927, developed the Uniform Building Code (UBC), primarily used in the Midwest and Western United States. Finally, in 1940, the Southern Building Code Congress International (SBCCI) was established, and it developed the Standard Building Code (SBC), which was primarily used in the Southern United States.

Where are the Codes Today

In 1994, representatives from BOCA, ICBO, and SBCCI began the process of developing a comprehensive code to use nationally. The First Edition of the IBC (from 1997), updates every three years.

The current International Code Council codes are:

  • Building Codes
    • Building Code
    • Existing Building Code
    • Green Construction Code
    • Zoning Code
  • Mechanical/HVAC Codes
    • Mechanical Code
    • Energy Conservation Code
  • Plumbing Building Codes
    • Plumbing Code
    • Private Sewage Disposal Code
    • Fuel Gas Code
  • Fire Building Codes
    • Fire Code
  • Residential Building Codes
    • Residential Code
  • Other Codes
    • ICC Performance Code
    • Property Maintenance Code
    • Swimming Pool and Spa Code
    • Wildland Urban Interface Code

Additionally, the National Fire Protection Association (NFPA) publishes a number of Codes and Standards including:

    • National Electrical Code® – NFPA 70
    • Health Care Facilities Code – NFPA 99
    • Life Safety Code® – NFPA 101
    • Building Construction and Safety Code – NFPA 5000

Building Codes

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10 Must-Have PE Exam Resources


NOTE: As per the NCEES Examinees Guide, books, notes, notebooks, etc. are no longer
permitted in the testing room. This does not diminish the importance of these Test-Prep
Resources as a method of study and preparation. For example, taking the time to
assemble a resource library will naturally help you categorize and document your
study materials, help you determine what’s essential to pass the exam, and keep all
your resources in one, easy-to-access tool.

These 10 Must-Have PE Exam Resources should be at the top of your PE Exam Test-Day Checklist

These resources are specifically listed for those taking a Civil Engineering or Mechanical Engineering Exam but some are applicable to every test. Refer to the NCEES Examinee Guide for a list of approved and not approved items allowed in the exam room. Check out the links – the pictures are links, too – to find related information.

1 – Acceptable Form of ID

Acceptable forms of ID must be government issued and must include:

  • a valid expiration date
  • your name
  • date of birth
  • a recognizable photo
  • your signature

Valid U.S. military IDs that do not include a signature will be accepted.

2 – Exam Authorization

Bring a printed copy of your exam authorization to prove that you’re registered and approved to take the exam. This will help in avoiding delays at check-in.

3 – International Building Code

We recommend purchasing a copy of the International Building Code. After the exam, you can either use it in your practice or attempt to resell it.

4 – Approved Calculator

Review the Approved Calculators List on NCEES.org.

  • Don’t try to outsmart the system on this one.
5 – Timer

A timer is a definite must-have for the test. With 80 questions on the exam and eight hours to finish, that only gives you six minutes per question. In this six minutes, you must:

  • read the question
  • determine what the question is asking for
  • find your resources
  • solve the problem
  • mark the answer sheet

For the majority of questions – hopefully – this will be plenty of time, but there is always a certain percentage of the questions that will take you more than six minutes to solve/answer. By using a timer, you can stay on schedule, picking up a few precious minutes here and there to use towards those more difficult questions. The last thing you want on test day is to be well short of finishing when the proctor indicates you have 30 minutes left.

Note: Cell phones are NOT allowed in the exam room at any time. Do not plan to use your smart phone app as your timer or else …

6 – Resource Library

In addition to the International Building Code, you need to have those resources that are specific to your particular exam. A good rule is that if you used a resource – code book, handbook, chart, graph – when solving practice problems during your preparation, then include them in your Test-Prep Resource Library©*

If you used something once or twice, make a copy of that particular resource only. Your Resource Library is not intended to be every notebook, textbook, study guide, Post-It Note®, scrap of paper you can find. You will see people hauling in so much material you might feel under-prepared.

Don’t!

There is no way they can use all that stuff in the limited amount of time available. The good news is you’ll be amused by the fact they spent a lot of time and effort getting their collection to the test site while you waltzed in carrying a box of binders.

7 – Binders of Solved Example Problems

If you’ve taken any of the Crash Courses we offer, then you are well aware of our endorsement for working example problems. You can take all the review courses you can find, read all the study guides you want, and use any number of other preparation routines, but you still won’t beat the benefit of working problems. We built our Test-Prep Resource Library©* by finding example questions for each of the topics shown for the specific exam. Working through the problems will allow you to add to the supplemental materials you found helpful. Then, assemble everything into your five-binder library. These five binders, plus a few Code books, are all you will need to pass your PE Exam.

8 – Equations, Formulas, & Conversions

Although this one seems a bit obvious, I can assure you there will be a question or two that requires some obscure equation or conversion factor you don’t have. Find a good source of equations and conversion factors – in a book or online – and add those to your library.

9 – Engineering Economics Resources

Almost all the PE Exams have an Engineering Economic analysis problem or two. During your preparation time, determine the most typical type of analysis problems – depreciation, present worth, future worth, equivalent uniform annual benefits – and find applicable tables and charts to solve these problems.

10 – Snacks and Nonalcoholic Drinks

Make certain your snacks (i.e. hard candy, candy bars, gum) and drinks can be opened and consumed with little or no noise that would disturb the other examinees. There is nothing more annoying in a testing room than someone attempting to quietly open a candy wrapper. In their efforts, they usually make considerably more noise than if they would have just opened it normally. Your goal is to quickly have a snack without anyone noticing.

That’s it … our 10 Must-Have PE Exam Resources!


10 Must-Have PE Exam Resources

Engineering Design Resources

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Life Safety Systems

This blog post will discuss how to incorporate some Life Safety Systems knowledge into your exam preparation.

So…how is your exam prep coming along?

“When it’s time to die, let us not discover that we have never lived.”
~ Henry David Thoreau

Even though a weekend may be at hand, don’t let up on preparing for the exam. There will be plenty of weekends after you become a Licensed Professional Engineer.

However, do yourself a favor…

Take some time – and in the weeks to come – to decide for yourself what truly makes you happy. What will you be proud of at the end of your life? What will you regret not having done? Make a list of all the things you want to:

  • Be: What kind kind of person – friend, parent, neighbor, engineer – do you want to be? How do you want to be remembered? What legacy do you want to leave?
  • Do: What adventures do you want to have? Do you want to travel? Sky-dive? Scuba-dive? Save the rain forests? Feed the hungry? What would make you “feel alive?”
  • Have: What material things do you want? A bigger house? A sports car? A boat? Abundant resources to help the needy? These things can be “trophies” or “toys.” Or they can be resources to benefit others.

Give yourself this time to decide in advance what you want to accomplish in your life. What does success look like to you? Don’t get to the end of your life only to “discover that you never lived.”

Now for the Life Safety System information…

The Uniform Building Code and the Life Safety Code – NFPA 101 – are the two primary resources we will focus on in this post. Keep in mind that the National Electrical Code, NFPA 13, and other Codes and Standards contain Life Safety information.

Life Safety SystemsAction Items:

  1. Get a copy of the International Building Code®. Tag or make copies of sections that relate to Life Safety Systems. At a very minimum:
    • Special Detailed Requirements Based on Use and Occupancy (Chapter 4)
    • Types of Construction (Chapter 6)
    • Fire and Smoke Protection Features (Chapter 7)
    • Fire Protection Systems (Chapter 9)
    • Means of Egress (Chapter 10)
  2. Get a copy of NFPA 101 – The Life Safety Code®. Tag or make copies of sections that address issues like:
    • Generators
    • Batteries
    • Exit Lighting
    • Fire Alarms
  3. Look through NFPA 13 for items directly related to Life Safety Systems

Add a section in your Test-Prep Resource Library©* for Life Safety Systems. Put these items – and others you discover as you prepare – in this section.

*NOTE: As per the NCEES Examinees Guide, books, notes, notebooks, etc. are no longer permitted in the testing room. This does not diminish the importance of a Test-Prep Resource Library© as a method of study and preparation. Taking the time to assemble a resource library will naturally help you categorize and document your study materials, help you determine what’s essential to pass the exam, and keep all your resources in one easy-to-access tool.


Life Safety Systems

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Building Envelope Analysis

Building Envelope Analysis

Today’s topic is Building Envelope Analysis, but before we start …

“In life you need either inspiration or desperation.”

~ Tony Robbins

Webster’s dictionary defines INSPIRATION as “something that makes someone want to do something or that gives someone an idea about what to do or create; a force or influence that inspires someone.”

DESPERATION is defined as “a strong feeling of sadness, fear, and loss of hope.”

You are at a point in your career where you have:

  1. Been supported, encouraged, mentored, and positively influenced – INSPIRATION, or
  2. Been left to fend for yourself, learning to be an engineer on your own – DESPERATION

Although in any endeavor, there is a certain amount of learning-by-experience and trial-by-fire, the best way for someone to realize and reach their full potential is to have a mentor. Better yet, have more than one mentor who teaches, guides, and encourages.

Unfortunately, the sad truth is that most engineers who run their own business, or who ascend to a position of leadership in an already established firm, learned what they know on their own. Either they didn’t have positive, knowledgeable, and encouraging role models, or they arrogantly shunned available support and are now passing these traits on to the next generation of engineers.

However, there are alternatives.

EngineeringDesignResources.com‘s goal is to help, inform, encourage, and support those working in building design and construction. Our sole purpose and passion is to be the “something that makes someone want to do something or that gives someone an idea about what to do or create” through information, resources, and community. Take what you need from these posts, ask for help when you need it, and then, we can then pass that knowledge and INSPIRATION on to others.

BUILDING ENVELOPE ANALYSIS

As a building designer, one of your charges is to design and specify heating, ventilating, and air-conditioning systems for buildings. These systems can be as simple as ventilation fans for air movement or indoor air quality up to highly specialized air treatment systems. In addition, you may be required to provide input into the building design, especially when it comes to building materials.

Both of these functions require knowledge and mastery of Building Envelope Analysis. By learning these skills, you make yourself a valuable part of the whole Design Team. You will gain the respect of Architects, Owners, and Contractors as well as other Building Design professionals.

For your Test-Prep Resource Library©*, you want to find and include the following Building Envelope Analysis information – density, conductivity, conductance, and resistance or U-values – for:

Building Materials

Load Calculations for Building Envelope Analysis:

  • For roofs, walls, and glass conduction: q = U x area x CLTD
  • For glass solar: q = area x SC x SHGF x CLF
  • Conductivity = k in BTU per (hour)(square foot)(temperature difference)
  • Conductance = C in BTU per (hour)(square foot)(temperature difference)
  • Resistance (R) = 1/k or 1/C in (hour)(square foot)(temperature difference) per BTU
  • U-value = 1/R in BTU per (hour)(square foot)(temperature difference)
  • Available from ASHRAE or search online:
    • Cooling Load Temperature Difference (CLTD) tables
    • Shading Coefficients (SC) tables
    • Solar Heat Gain Factor (SHGF) tables
    • Cooling Load Factor (CLF) tables
  • Weather Data

NOTE: As per the NCEES Examinees Guide, books, notes, notebooks, etc. are no longer permitted in the testing room. This does not diminish the importance of a Test-Prep Resource Library© as a method of study and preparation. Taking the time to assemble your own library will naturally help you categorize and document your study materials, help you determine what’s essential to pass the exam, and keep all your resources in one easy to access tool.

In conclusion, using this Building Envelope Analysis information and a few quick calculations, you can be a driving force in the overall building design and system selections – building skin, structural, and HVAC. Set up a model on a laptop computer or tablet prior to a design meeting in order to quickly change and modify building dimensions, directions, and materials. You will assist the Design Team and Owner in making decisions, and you have made yourself a valuable part of the Project Team.


Building Envelope Analysis

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Any resemblance in the images in this material to actual people or locations is merely coincidental. EngineeringDesignResources.com prohibits reprinting, copying, changing, reproducing, publishing, uploading, posting, transmitting, or using in any other manner images in this material.

PE Exam Success – The 10 Best Ways To Be Prepared

PE Exam Success – The 10 Best Ways To Be Prepared explains the top methods to dramatically increase your odds for success on the PE Exam.

PE Exam Success Results Vary Primarily Due To The Use Of Effective Exam Preparation Methods …

Or Not!

PE Exam Success

Prepare Smarter Not Harder!

As you are preparing to take an engineering PE exam, it will help to keep these in mind:

1 – Build A Solid Test-Prep Resource Library©*

*NOTE: As per the NCEES Examinees Guide, books, notes, notebooks, etc. are no longer permitted in the testing room. This does not diminish the importance of a Test-Prep Resource Library© as a method of study and preparation. Taking the time to assemble a resource library will naturally help you categorize and document your study materials, help you determine what’s essential to pass the exam, and keep all your resources in one easy-to-access tool.

This one is a must-do. Of all the other nine PE Exam Success – The 10 Best Ways To Be Prepared ideas listed here, this one, in our opinion, is by far the most important.

If you will take the time to:

  • Collect all the relevant information pertaining to each of the topics shown for your particular test, including:
    • Example PE Exam Problems with Solutions
    • Equations
    • Commentary
    • Charts and Tables
  • Assemble the information into binders.
  • Devise some method of retrieval to locate information quickly.
  • Spend a portion of your allotted study time to review and fine-tune your reference binders.

…your odds of successfully passing the PE Exam will dramatically increase.

The Study Guides found at EngineeringDesignResources.com are full of example problems, equations, commentary, and ideas for your Test-Prep Resource Library©

2 -Know the Codes

Depending on which PE Exam you are taking, it would be well worth your time to spend time reading through and becoming very familiar with the Code – or Codes – that are primary to your industry, such as:

  • Mechanical Engineering – The International Mechanical Code, The International Energy Efficiency Code, and The International Plumbing Code
  • Electrical Engineering – The National Electrical Code and The Life Safety Code – NFPA 101
  • Civil Engineering – The International Building Code
  • Structural Engineering – The International Building Code
  • Architectural Engineering – The International Codes – Building, Mechanical, Energy Efficiency, and Plumbing – and The National Electrical Code
3 – Know The Format

Most of the PE Exams are 80 multiple choice questions taken over an eight hour period – 40 questions in the four-hour morning session and 40 questions in the four-hour afternoon session.

That means 480 minutes to read the questions, understand what’s being asked, find the applicable resource, work the problem, and mark the answer on the test page – the Scantron.

That’s only SIX minutes per question.

This may seem like a lot of time … but it’s not.

Use some of your preparation time practicing answering questions at the rate of one every six minutes. This will help you gauge your pace for test day.

4 – Plan Your Study Time

Whether you have 12 months, 12 weeks, or 12 days – hopefully not 12 days – you can plan your time wisely to maximize the benefits of your study effort. Most likely, you have a job, maybe a family, other commitments, and probably some interests that take time. Sit down with the test outline for your particular PE Exam – found at NCEES.ORG – and plan out how to cover all the material you need to review in the amount of time available.

Refer back to ideas #1, #2, and #3 above.

Work through the process systematically, and you will be successful.

5 – Use The Right Tools

What tools does your industry use to make design easier?

  • Psychrometric Charts
  • Bending Stress Tables
  • Equations

PE Exam Success - The 10 Best Ways To Be Prepared

Whatever these tools are, make sure you have them on hand in your Test-Prep Resource Library© and be able to use them quickly. The last place to learn to use a tool is when you need it – under pressure.

Also, log onto NCEES.ORG for information on what’s allowed into the testing centers and what calculators are acceptable.

6 – Take Sample Tests

Ways to find sample PE Exams:

  • Search the internet
  • Search Amazon.com
  • Search your industry’s applicable websites – i.e. for Civil Engineering go to www.asce.org.

If you need assistance locating any resources, Contact Us.

7 – Work To Your Strengths

As with everything in life, we perform better and are more successful when we are doing those things we have already mastered. Only little gains will be realized trying to learn something new and gain proficiency while under the pressures of a deadline – test day.

As such, take the time to figure out what you know very well. Spend the majority of your time on these subjects. Polish your expertise, gain new insights, practice your skills. This hyper-focus on strengths will give you the confidence you need on Test Day to knock out a good portion of the questions.

8 – Get Help On Your Weaker Topics

For those topics that aren’t as engrained as you’d like, use some of your preparation time getting help from someone who is an expert. There are plenty of people who are willing and eager to help you attain your PE. Look for mentors in:

  • Your current company
  • Companies with which you previously worked
  • Local professional societies
  • National professional societies
  • Local schools, colleges, and universities
  • Online
9 – Exploit The Odds

Most of the PE Exams – with the exception of the Structural Depth exams – are 80 multiple choice questions, taken over an eight hour period. To pass the exam and receive your PE License, you need to correctly answer 70% of the questions.

That’s only 56 right answers – so weigh the odds in your favor!

Take the Electrical PE Exam as an example:

  1. You have a lot of experience in:
    • General Power Engineering – Measurement and Instrumentation (7.5% or six questions)
    • General Power Engineering – Special Applications (10% or eight questions)
    • Circuit Analysis – Devices and Power Electronic Circuits (9% or seven questions)
    • Rotating Machines and Electromagnetic Devices – Rotating Machines (12.5% or ten questions)
  2. Get tutoring in:
    • Transmission and Distribution – System Analysis (12.5% or ten questions)
    • Transmission and Distribution – Protection (10% or eight questions)
  3. Spend enough time reading through and learning the codes:
    • General Power Engineering – Codes and Standards (12.5% or ten questions)

That totals 59 correct answers – more than enough to pass the PE Exam.

10 – Eat Well And Get Plenty Of Rest

This one is really a no-brainer, but it never hurts to hear it again. Take the time to adjust your diet leading up to the PE Exam. Eat plenty of fruits, vegetables, poultry, fish, nuts, and lean protein. Drink lots of water – at least 1/2 ounce for every pound. So if you weigh 185 pounds that’s 93 ounces of water per day (12 x 8oz glasses).

Bonus – Prepare for Test Day in Advance

Lastly, begin to assemble all of your test-day resources well in advance of the PE Exam. You will probably want to pack:

  • Healthy snacks
  • Drinks – like water
  • Clothing or jackets that can be taken on or off quickly and quietly
  • Extra money
  • Any forms or documents that may be required at the testing facility
  • Directions to the testing facility
  • Hotel reservations, if needed
  • Your Test-Prep Resource Library©

If you will begin putting these things together in advance, then you won’t have to worry about them the night before the PE Exam.

You can find useful and effective study materials to help you prepare for your PE Exam at:

PE Exam Study Guides


PE Exam Success – The 10 Best Ways To Be Prepared

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Professional Engineering Exam

Professional Engineering Exam

The Professional Engineering Exam is the final step a graduate engineer must take in order to sign and seal engineered drawings and perform, or supervise others performing, engineering calculations.

The Professional Engineering Exam is administered twice  per year, in April and October. Each eight-hour test day is divided into a four-hour morning session, a lunch break, and a four-hour afternoon session. Each session consists of 40 multiple choice questions that will measure the engineer’s grasp and understanding of the subject matter.

Professional Engineering Exams are available in the following disciplines:

  • Agricultural
  • Architectural
  • Chemical
  • Civil:
    • Construction
    • Geotechnical
    • Structural
    • Transportation
    • Water Resources and Environmental
  • Control Systems
  • Electrical and Computer:
    • Computer Engineering
    • Electrical and Electronics
    • Power
  • Environmental
  • Fire Protection
  • Industrial and Systems
  • Mechanical:
    • HVAC and Refrigeration
    • Mechanical Systems and Materials
    • Thermal and Fluids Systems
  • Metallurgical and Materials
  • Mining and Mineral Processing
  • Naval Architecture and Marine
  • Nuclear
  • Petroleum
  • Software
  • Structural

Resources to prepare for the examinations are available in the form of books, CDs, online classes, classes at local universities, etc. Refer to the National Council of Examiners for Engineering and Surveying (NCEES) for additional study resources and to get specific test information and areas of concentration for each discipline.  You may also find study resources at your discipline’s professional society.

PE Exam Pass Rates

According to data from NCEES, the most current pass rates for the Professional Engineering Exam are:

Improving PE Exam Pass Rates

You can greatly improve your odds of success passing a Professional Engineering Exam by:

  1. Being thoroughly prepared with organized, structured study
  2. Working as many example problems as possible
  3. Utilizing an adequate Test-Prep Resource Library©*

*NOTE: As per the NCEES Examinees Guide, books, notes, notebooks, etc. are no longer permitted in the testing room. This does not diminish the importance of a Test-Prep Resource Library© as a method of study and preparation. Taking the time to assemble a resource library will naturally help you categorize and document your study materials, help you determine what’s essential to pass the exam, and keep all your resources in one easy-to-access tool.


Professional Engineering Exam

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Any resemblance in the images in this material to actual people or locations is merely coincidental. EngineeringDesignResources.com prohibits reprinting, copying, changing, reproducing, publishing, uploading, posting, transmitting, or using in any other manner images in this material.

Heating and Air Conditioning Loads

Heating and Air Conditioning Loads provide the design engineer with rates of heat transfer through the building materials and surfaces – walls, floors, roofs, windows, etc. – and the contribution to the heating or air conditioning systems by various building components – people, lighting, equipment, etc. With this information solidly in hand, the engineer can proceed to design the multiple components of the building’s HVAC system.

Heating and Air Conditioning Loads

Central Plant:

  • Chillers
  • Cooling Towers
  • Boilers
  • Pumps

Air Side:

  • Air Handling Units
  • Ductwork
  • Exhaust Fans
  • Outside Air Systems
Summer Heating and Air Conditioning Loads

The peak – or highest – cooling load during the summer is that amount of heat removed to maintain the room’s design temperature. Factors that contribute to a building’s cooling load are:

  • The sun, which heats up the building exterior and then transfers into the building through walls, roofs, windows, etc.
  • Items within the building that produce heat such as people, lighting, equipment
  • The building’s geographic location
  • Maintaining the interior design temperature
Winter Heating and Air Conditioning Loads

The peak – or highest – heating load during the winter is the amount of heat added to maintain the room’s design temperature. Factors that contribute to a building’s heating load are:

  • Heat lost to the outdoors through walls, roofs, windows
  • The building’s geographic location
  • Maintaining the interior design temperature

The loads calculated for both heating and cooling are necessary to accurately size the equipment – heating and cooling systems, the air distribution systems – ductwork, diffusers, terminal boxes – and the ventilation system. A Heating and Air Conditioning Loads system that is incorrectly undersized will not be able to keep the building at the desired indoor temperature as required in the design. And a Heating and Air Conditioning Loads system that is incorrectly oversized will constantly cycle on/off and will be unable to maintain the proper humidity levels within the building. This can lead to larger problems such as equipment damage, occupant discomfort, and mold growth.

Calculating Heating and Cooling Loads

Heating and Air Conditioning Loads are mostly calculated using computer programs such as Elite Software’s CHVAC and RHVAC programs, Carrier Corporation’s HAP program and Trane’s TRACE program. These and many other programs on the market are highly specialized, can require an extreme amount of data input, produce large quantities of output, are very accurate in terms of Heating and Air Conditioning Loads, and are usually quite expensive. These programs are often necessary when it comes time to perform the actual equipment sizing, selection, and specification.

A design engineer who didn’t spend the time manipulating wall construction, roof construction, occupancies, equipment loads, and lighting configurations would not be providing the building owner with professional service. In designing the building’s HVAC systems, it is imperative to use the most realistic and accurate computer model of how the building will function in both heating and cooling environments and at different times of the day, week, month, or year.

But there are times when this accuracy and time/effort investment are not fiscally reasonable. For example, in the early stages of the design process, when the owner, architect, and engineer are meeting to determine the best course of design to pursue, it is important to understand the impact of the HVAC system on the overall design especially as it relates to space requirements. It becomes convenient to have a method by which the engineer can estimate these space requirements by quickly sizing the equipment required based on the current architectural design and extrapolating out to come up with mechanical room sizes, access into/out of and overall location within the building.

Load Calculation Worksheet

The Heating and Air Conditioning Loads Calculation Worksheet is one-page “snapshot” design tool based in Microsoft Excel utilizes psychrometric equations to solve and provide data for heating and air conditioning designs. The simplicity and unique compactness allows the design engineer to input, change, and manipulate multiple HVAC load variations, altering and adjusting on the spot, with the output immediately available on screen. The benefit to the engineer, architect and owner is in the speed of decision making. If the design team can quickly arrive at the most beneficial building design with respect to building materials, site orientation, occupancies, hours of operation, etc., this saves the overall project budget in terms of time – meetings, phone calls, design – money and frustration.

Air Handling Unit Selection Worksheet

The Air Handling Unit Selection Worksheet is designed to be used in conjunction with the Heating and Air Conditioning Loads Calculation Worksheet, although it can stand alone. The Air Handling Unit Worksheet uses parameters such as sensible load, latent load, and total load to provide the remaining variables needed to select and specify air handling units. The worksheet also allows the design engineer to input known static pressures to get a more realistic estimation of the overall Internal and Total Static Pressures for the units.


Heating and Air Conditioning Loads

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Project Management Cost Estimate Worksheet

Project Management Cost Estimate WorksheetProject Management Cost Estimate Worksheet calculates project fee which, in most cases, is the driving force behind every design and construction project.

Project fee determines what the building looks like – size, shape, structure, building materials, air conditioning and heating systems, lighting, landscaping, etc., how much time the design professionals can devote to the project, how many design professionals will need to be allocated to the project and for how long, how much time and how many trips the design team can make to the project site, and ultimately, how much profit each participant is going to realize at the end of the project.

In determining the project fee that the design professionals should charge involves many factors. Some of the more identifiable, specific information needed is:

  • Scope of the project
  • Time duration for the design
  • Size of the project
  • Building systems
  • Overall construction budget
  • Project Management Cost Estimate Worksheet
  • Acquiring additional training or equipment before or during design

Additionally, account for issues that can sometimes be sensitive in nature, such as:

  • Past relationships with the Architect of Record, Owner, or Contractor
  • Ease of working with other consultants and building officials in the jurisdiction of the project
  • Experience and abilities of in-house design professionals
  • Potential for designing the project at a reduced fee for some future benefit such as good-will, additional projects, or publicity

There are numerous ways to arrive at a project fee that will satisfy most of the above stated issues. By utilizing the Project Management Cost Estimate Worksheet, a more consistent and accurate fee can be estimated.

CONSULTANT FEE AS PERCENTAGE OF CONSTRUCTION BUDGET

If the overall construction budget established by the owner is known and if the Project Manager can determine baseline percentages for the different parts of the design and construction process, then a fee can be determined as follows:

Various Methods for an MEP Consulting Engineer
1 – Percent of General Construction
  • Total General Construction Estimate = $50,000,000
  • 25% of Total General Construction = MEP Portion of the Construction = $12,500,000
  • MEP Design Fee:
    • as Percentage of the MEP Construction (4%):
      • Design Fee = $12,500,000 x 4% = $500,000
    • as Percentage of General Construction (25% x 4% = 1%):
      • Design Fee = $50,000,000 x 1% = $500,000
2 – Percent of Architect’s Fee
  • Total General Construction Estimate = $50,000,000
  • 10% of Total General Construction – Architect’s Fee = $5,000,000
  • MEP Design Fee:
    • as Percentage of Architect’s Fee (10%):
      • Design Fee = $5,000,000 x 10% = $500,000
3 – Total Staff Requirements by MEP Consultant
  • Staff Costs (Salary Plus Overhead)
    • Principal: $150 per hour
    • Project Manager: $120 per hour
    • Senior Engineer: $100 per hour
    • Design Engineer: $75 per hour
    • CADD: $50 per hour
    • Administrative: $40 per hour
  • Project Requires the Following Time Commitments:
    • Principal: 30 hours
    • Project Manager: 350 hours
    • 3 Project Engineers: 250 hours each
    • 3 Design Engineers: 750 hours each
    • 2 CADD: 1,500 hours each
    • Administrative: 250 hours
  • The staff costs would total $450,250
  • Assuming a 10% profit, the total MEP fee for this project would be $500,278 (or $450,250 ⁄ 0.9).

Project Management is a complex, hands-on, task specific occupation that requires both the science of managing numbers and budgets, as well as the art of managing people and project vision.

A tool the Project Manager can utilize to standardize and automate the fee estimation part of the job is the Project Management Cost Estimate Worksheet. Manipulate this worksheet to change costs, percentages, pay rates, profits, markups, and project scope. It also contains a worksheet to estimate the amount of time required by the design staff on a drawing-by-drawing basis if that is customary to you or your firm.


Project Management Cost Estimate Worksheet

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HVAC Load Calculations Worksheet

HVAC Load Calculations Worksheet

HVAC Load Calculations Worksheet specifically accelerates initial design decisions and system selection. The simplicity and unique compactness allows the design engineer to input, change, and manipulate multiple HVAC load variations on the spot, with the output immediately available on screen. The output is a one-page form showing all the pertinent data and design conditions needed to accurately select the proper heating, ventilating, and air-conditioning equipment to satisfy the space conditions.

Other HVAC Worksheets

Not only are there are many HVAC Load Calculations Worksheets on the market that are highly specialized, require an extreme amount of data input, produce large quantities of output, are very accurate in terms of HVAC loads, but they are usually quite expensive. These programs are often necessary when it comes time to perform the actual equipment sizing, selection, and specification. A design engineer who doesn’t spend the time manipulating wall construction, roof construction, occupancies, equipment loads, and lighting configurations would not be providing the building owner with professional service. It is imperative to use the most realistic and accurate computer model in designing the building’s HVAC systems. This will determine how the building will function in both heating and cooling environments and at different times of the day, week, month, or year.

Stages

However, there are times when this accuracy and time/effort investment are not fiscally reasonable. For example, in the early stages of the design process, when the owner, architect, and engineer are meeting to determine the best course of design to pursue, it is important to understand the impact of the HVAC system on the overall design especially as it relates to space requirements. It becomes convenient to have a method, such as the HVAC Load Calculations Worksheet, by which the engineer can estimate these space requirements by quickly sizing the equipment required based on the current architectural design and extrapolating out to determine mechanical room sizes, access into/out of, and overall location within the building.

At this stage of the design, the owner, architect, and engineer make preliminary decisions and select the type of system depending on the total load, the desired system control, the required space setpoints, etc. Further information and design considerations on the HVAC Load Calculations Worksheet topic are available on the HVAC Loads page.


HVAC Load Calculations Worksheet

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Air Handling Unit Design Worksheet

The Air Handling Unit Design Worksheet compliments the HVAC Load Calculation Worksheet. This worksheet assists the design engineer in accelerating initial design decisions and system selection. The simple and straight forward worksheet layout allows the design engineer to input, change, and manipulate multiple AHU variations to arrive at a suitable selection. The output from the worksheet is a one-page form showing all the pertinent data and design conditions needed to accurately select the proper air handling unit equipment to satisfy the space conditions.

Air Handling Unit Design Worksheet

Other AHU Programs

There are other Air Handling Unit Design Worksheet programs on the market that require more data input, produce large quantities of output, are very specific in terms of air handling unit selection. These programs are either manufacturer specific or are very expensive. The use of these programs is often necessary and beneficial when it comes time to perform the actual equipment sizing, selection, and specification. A design engineer who doesn’t spend the time manipulating air handling unit configurations would not be providing the building owner with professional service. It is imperative to design and select the most realistic and accurate systems and equipment for the building so that the owner receives the most economical and functional building possible. However, due to budget or time constraints, there are times when the more sophisticated unit selection programs are not fiscally reasonable.

For Example

In the early stages of the design process, when the owner, architect, and engineer are meeting to determine the best course of design to pursue, it is important to understand the impact of the HVAC system equipment on the overall design especially as it relates to space requirements. It becomes convenient to have a method by which the engineer can estimate these space requirements by quickly sizing the equipment required based on the current architectural design and extrapolating out to come up with mechanical room sizes, access into/out of and overall location within the building.

It’s also at this stage of the design when the owner, architect, and engineer make preliminary decisions about the type of systems that will be used. The team can narrow down or select the types of systems, depending on the total load, the desired system control, the required space setpoints, etc. Further information and design considerations on the Air Handling Unit Design Worksheet can be found on the HVAC Load Calculation Worksheet.


Air Handling Unit Design Worksheet

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Any resemblance in the images in this material to actual people or locations is merely coincidental. EngineeringDesignResources.com prohibits reprinting, copying, changing, reproducing, publishing, uploading, posting, transmitting, or using in any other manner images in this material.