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]]> Concrete cross section

In the last post, I talk about how to determine the required reinforcing for a rectangular beam. To elaborate more on the same topic, I am going to show you how to actually calculate out the capacity (using my handy dandy flowchart).

This most likely is just a refresher for many of you but it doesn't hurt to get more familiar with the calculation (especially if you haven't designed concrete for awhile).

The Goal

To determine the moment capacity, \phi { M }_{ n }, without having to memorize anything – you just need to follow the flowchart.

Flowchart

This flowchart also includes the stress/strain distribution diagram shown above.

Click Here to get the Flowchart

Given

  • { A }_{ s }\: (or \rho) = Provided reinforcing steel (or steel ratio).
  • {f}_{c}^{'}= Specified compressive strength. This is typically 3000, 4000, or 5000 psi.
  • {f}_{y}= Specified yield strength of reinforcement. Usually 60,000 psi for new buildings and 40,000 psi for older buildings.
  • b= Width of the beam.
  • d= Usually the total beam depth – cover – 1/2 of the rebar diameter.

Determine

  • \phi { M }_{ n }= Moment capacity of the section.

Quick Check

I've demonstrated the following “quick check” in an earlier post:

    \[ \frac{{ M }_{ u }}{4d}={A}_{s}$ \]

If we set \phi { M }_{ n }={M}_{u} and rearrange the equation, we get:

    \[ {\phi { M }_{ n }}={A}_{s}{4d}=?\:kip\cdot ft \]

where the units for {A}_{s} is [in²] and d is [in].

Step-by-Step

# Equation Action Notes/Explanation
1 a=\frac { { A }_{ s }{ f }_{ y } }{ 0.85{ f }_{ c }^{ ' }b } Calculate This calculates the size of the compression stress block.
2 j=\frac { \left( d-0.5a \right) }{ d } Calculate This is the ratio between the T-C moment arm and d. It'll be used in step [8] to obtain the moment capacity.
3 c=\frac { a }{ { \beta }_{ 1 } } Calculate Location of the neutral axis from top fiber. See previous post/flowchart step [5] for the calculation of { \beta }_{ 1 } }.
4 { \varepsilon }_{ t }=0.003\frac { d-c }{ c } Calculate This is the strain in the tension reinforcement.
5 { \varepsilon }_{ t }\ge 0.005? Check This checks whether the section is tension or compression controlled per er ACI 318, 9.3.2.2.
6 \phi =MAX\begin{bmatrix} 0.48+83{ \varepsilon }_{ t } \\ 0.65 \end{bmatrix} Calculate if answer in [5] is no (i.e., compression controls). If compression controls, you have to reduce the \phi factor based on this formula.
7 \phi =0.90 Calculate if answer in [5] is yes (i.e., tension controls). This is the \phi factor for tension controlled section.
8 \phi { M }_{ n }=\phi { f }_{ y }{ A }_{ s }jd Calculate The moment capacity.
9 { \rho }_{ b }=0.85\left( \frac { 87,000{ \beta }_{ 1 }{ f }_{ c }^{ ' } }{ { f }_{ y }\left( 87,000+{ f }_{ y } \right) } \right) Calculate (Optional) This is the reinforcement ratio that will cause “balanced strain condition” which is when these two events occur at the same time:

  1. Tension reinforcement yields.
  2. Strain in the concrete reaches 0.003.

In terms of design, you just want to make sure that your reinforcement ratio is less than this calculated value to prevent brittle failures.

Example

Given

  • { A }_{ s }=3.16\:{in}^{2} (4-No.8)
  • {f}_{c}^{'}=3000\:psi
  • {f}_{y}=60,000\:psi
  • b=12\:in
  • d=20\:in

Quick Check

    \[ { \phi { M }_{ n } }={ A }_{ s }{ 4d }=3.16\cdot 4\cdot 20=253\: kip\cdot ft \]

Remember that this quick check is just an estimate. The point is just to make sure that we didn't mess up the actual calculation somewhere along the way.

We'll verify the real capacity in the table below.

Use the Flowchart

# Equation Results Notes/Explanation
1 a=\frac { { A }_{ s }{ f }_{ y } }{ 0.85{ f }_{ c }^{ ' }b }  6.1961 in
2 j=\frac { \left( d-0.5a \right) }{ d }  0.8451
3 c=\frac { a }{ { \beta }_{ 1 } } 7.2895 in {\beta}_{1} is calculated to be 0.85 for {f}_{c}^{'}=3000\:psi.
4 { \varepsilon }_{ t }=0.003\frac { d-c }{ c }  0.0052
5 { \varepsilon }_{ t }\ge 0.005? Yes, tension controls.
6 \phi =MAX\begin{bmatrix} 0.48+83{ \varepsilon }_{ t } \\ 0.65 \end{bmatrix}  Not applicable
7 \phi =0.90 0.90
8 \phi { M }_{ n }=\phi { f }_{ y }{ A }_{ s }jd 240 kip-ft This is pretty close to the quick check (253 kip-ft) which means we probably didn't screw up arithmetically.
9 { \rho }_{ b }=0.85\left( \frac { 87,000{ \beta }_{ 1 }{ f }_{ c }^{ ' } }{ { f }_{ y }\left( 87,000+{ f }_{ y } \right) } \right)  0.0214 Compares with \rho={A}_{s}/bd=0.0132, balanced reinforcement ratio is greater; therefore we will not get brittle failure which is good.

Done!

There you have it. Is this helpful? Let me know in the comments below.

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]]> https://structuralengineerhq.com/determine-the-capacity-of-a-reinforced-concrete-beam-with-tension-reinforcement/feed/ 2 718 Reinforced Concrete Design (with Flowchart) – Concrete Beam with Tension Reinforcement Only https://structuralengineerhq.com/reinforced-concrete-design-with-flowchart-concrete-beam-with-tension-reinforcement-only/ https://structuralengineerhq.com/reinforced-concrete-design-with-flowchart-concrete-beam-with-tension-reinforcement-only/#comments Mon, 14 Apr 2014 16:12:22 +0000 http://structuralengineerhq.com/?p=455 Have you heard of Mu/4d? That’s something I learned at work from one of my bosses who has been a licensed SE since 1984! It’s basically a quick way to check your numbers for concrete flexure (which I will show you later in the post). Apparently that’s how engineers used to do quick checks – […]

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]]> Concrete cross section

Have you heard of Mu/4d?

That’s something I learned at work from one of my bosses who has been a licensed SE since 1984! It’s basically a quick way to check your numbers for concrete flexure (which I will show you later in the post).

Apparently that’s how engineers used to do quick checks – there’s no reasons why we can’t still use the same technique today.

In this post, you will learn how to design a reinforced concrete beam step-by-step, with my “simple-to-follow” flowchart. By creating and using the flowchart, I was able to recall the info needed without having to memorize anything which I hope I can help you do the same.

The Goals

There a few things that I want to help you achieve by the end of the post:

  • To be able to come up with the required reinforcement without having to “re-read” anything.
  • Recall how to design without memorizing.
  • A step-by-step procedure that can be easily followed so that you don’t miss all the little “fine-prints” such as minimum/maximum reinforcement requirement…etc.
Note that the flowchart mainly addresses the design of a rectangular beam (not T-beams) with tension reinforcing only. T-beam design will come in a later post.

Assumptions

I want to point out that since you are taking the SE exam, you most likely have some idea about all of the concrete properties (brittle) and the design theories (compression zone…etc.) so I am not going to elaborate too much about them.

If you do need more info though, please let me know – I am more than happy to help.

Another thing I want to mention is that there are many many ways to do the same design and this is just the one that I am most familiar with.

OK let’s get to this!

Flowchart

The flowchart itself is pretty self-explanatory (maybe because I created it?) but I am going to give you a quick rundown anyway. Please do not hesitate to let me know if you got any questions.

Click Here to get the Flowchart

What's Given?

Usually, you should already have something to get started with on your design:

  • Mu: Factored design moment based on the worst case from your load combinations.
  • f'c: Specified compressive strength. This is typically 3000, 4000, or 5000 psi.
  • fy: Specified yield strength of reinforcement. Usually 60,000 psi for new buildings and 40,000 psi for older buildings.
  • b: Width of the beam.
  • d: Usually the total beam depth – cover – 1/2 of the rebar diameter. I am going to assume you know what this is.

What Are We Trying to Determine?

Ultimate goal is of course to find the reinforcements you need that makes the beam work.

Quick Check

    \[ \frac{{ M }_{ u }}{4d}=?\:in^2$ \]

Before you do anything, it’s a good idea to do this first. Like I mentioned in the beginning, it’s a very quick way to get a rough number for the reinforcement you need.

I know the units don’t make sense but just go with it and test it out. You want to make sure the unit for your “Mu” is [kip-ft] and “d” is [in]. The result will be in [in2].

I’ll show you an example at the end.

Step-by-Step Explanations

# Equation Action Notes/Explanation
1 \frac { { M }_{ u } }{ { f }_{ c }^{ ' }b{ d }^{ 2 } } =? Calculate You are going to calculate this number a lot. It's used for determining the \rho factor which you can see in the next item.
2 Use Appendix A Table (of the SE Reference Manual) Determine \omega This basically tabulates the equation \frac { { M }_{ u } }{ { f }_{ c }^{ ' }b{ d }^{ 2 } } =\omega (0.9-0.5294\omega) so that you don't have to plug in the numbers. For example, if you had calculated \frac { { M }_{ u } }{ { f }_{ c }^{ ' }b{ d }^{ 2 } }=0.1976, using the table, you get \omega=0.259. Pretty handy.Let me know if you don't have the table, I can create one and post it when I get a chance. You can also solve the equation using quadratic formula if needed.
3 \rho =\omega \frac { { f }_{ c }^{ ' } }{ { f }_{ y } } Calculate This is basically the reinforcement ratio you need. You still need to verify min/max and \phi…etc.
4 { \rho }_{ min }=MAX\left( \frac { 3\sqrt { { f }_{ c }^{ ' } } }{ { f }_{ y } } ,\frac { 200 }{ { f }_{ y } } \right) Calculate (make sure your units are in psi) This is the minimum reinforcement ratio required. I have tabulated the number for the most common case: if { f }_{ c }^{ ' }=3000\:psi and { f }_{ y }=60000\:psi, then { \rho }_{ min }=0.0033.
5 \beta _{ 1 }=\begin{cases} 0.85,\quad if\quad { f }_{ c }^{ ' }\le 4000\quad \\ 0.85-\frac { { f }_{ c }^{ ' }-4000 }{ 20000 } ,\quad if\quad 4000\le { f }_{ c }^{ ' }\le 8000 \\ 0.65,\quad if\quad { f }_{ c }^{ ' }>8000 \end{cases} Calculate This will be used in a couple of equations later.
6 \rho _{ max }=0.364{ \beta _{ 1 } }\frac { f_{ c }^{ ' } }{ f_{ y } } Calculate This is the maximum reinforcement ratio which was derived from the requirement of minimum net tensile strain at nominal strength.
7 { \rho }_{ req }=MIN\left[ MAX\left( \rho ,{ \rho }_{ min } \right) ,{ \rho }_{ max } \right] Calculate After comparing these three numbers, we should now know how much reinforcement is needed that meets both the minimum and maximum requirements.PS: I wrote it in this format because I am used to writing like this in Excel functions which I assume you might be as well.
8 \rho _{ t }=0.319{ \beta _{ 1 } }\frac { f_{ c }^{ ' } }{ f_{ y } } Calculate This is for checking to see if the beam is “tension controlled” or “compression controlled”. See below.
9 { \rho }_{ req }<\rho _{ t }? Compare If the statement is true, then we know that the beam is “tension controlled”.
10 { A }_{ s.req }={ \rho }_{ req }A Calculate This simply converts the ratio to an actual number so that you can decide on the number of bars and the size of bars.Note that this number is based on a tension controlled section and has already accounted for \phi = 0.9.
11 a=\frac { A_{ s }{ f }_{ y } }{ 0.85f_{ c }^{ ' }b } Calculate This is the size of the compression block (see diagram on the very top). We need this to calculate the location of neutral axis and the corresponding \phi factor if the section is compression controlled.
12 c=\frac { a }{ { \beta }_{ 1 } } Calculate Location of neutral axis from the top fiber.
13 \phi =MAX\left( \left( 0.23+\frac { 0.25 }{ \frac { c }{ d } } \right) ,0.65 \right) Calculate Corresponding \phi factor as mentioned earlier.
14 { A }_{ s.req(c) }={ A }_{ s.req }\left( \frac { 0.9 }{ \phi } \right) Calculate Revised (increased) reinforcement required since the section is “compression controlled” which has lower \phi.

Concrete Beam Design Example

Now let's run through this flowchart with an actual example.

Given

  • { M }_{ u }=225\: kip\cdot ft
  • {f}_{c}^{'}=3000 \: psi
  • {f}_{y}=60,000 \: psi
  • b = 12\:in
  • beam\:depth = 22\:in
  • d = 20\:in (say cover is 1-1/2″ and we are using #8 bar: 22" - 1.5" - 0.5" = 20")

Quick Check

    \[ \frac{{ M }_{ u }}{4d}=\frac{225}{4\times20 }=2.8125\:in^2$ \]

This is the quick and dirty way to check the required reinforcement. We'll come back to verify when we have an actual solution.

Flowchart

# Equation Results Notes/Explanation
1 \frac { { M }_{ u } }{ { f }_{ c }^{ ' }b{ d }^{ 2 } } =? 0.1875
2 Use Appendix A Table (of the SE Reference Manual) 0.243 Use the table, the number listed that is closest to 0.1875 is 0.1874 – which corresponds to \omega=0.243.
3 \rho =\omega \frac { { f }_{ c }^{ ' } }{ { f }_{ y } } 0.0122
4 { \rho }_{ min }=MAX\left( \frac { 3\sqrt { { f }_{ c }^{ ' } } }{ { f }_{ y } } ,\frac { 200 }{ { f }_{ y } } \right) 0.0033
5 \beta _{ 1 }=\begin{cases} 0.85,\quad if\quad { f }_{ c }^{ ' }\le 4000\quad \\ 0.85-\frac { { f }_{ c }^{ ' }-4000 }{ 20000 } ,\quad if\quad 4000\le { f }_{ c }^{ ' }\le 8000 \\ 0.65,\quad if\quad { f }_{ c }^{ ' }>8000 \end{cases} 0.85
6 \rho _{ max }=0.364{ \beta _{ 1 } }\frac { f_{ c }^{ ' } }{ f_{ y } } 0.0155
7 { \rho }_{ req }=MIN\left[ MAX\left( \rho ,{ \rho }_{ min } \right) ,{ \rho }_{ max } \right] 0.0122
8 \rho _{ t }=0.319{ \beta _{ 1 } }\frac { f_{ c }^{ ' } }{ f_{ y } } 0.0136
9 { \rho }_{ req }<\rho _{ t }? Yes; therefore tension governs.
10 { A }_{ s.req }={ \rho }_{ req }A 2.9171 in2 Compare to the quick calc we did above (2.8125 in2), we are fairly close! Therefore, we know that we didn't make any computational errors.Based on this, we will need 4-No.8 bars (0.79 in2 x 4 = 3.16 in2).Note that if the As you use is significantly larger than As.req, you should repeat steps 7 and 9 to ensure that you didn't exceed the maximum reinforcing and to ensure that tension still governs.For example:

    \[\rho=\frac{3.16}{12\times {20}}=0.0132\]

    \[ \rho_{max}=0.0155\:>\:0.0132 \]

It is still less than the max so we are OK.

    \[ \rho_{t}=0.0136\:>\:0.0132 \]

Tension still governs – we are OK here as well.
11 a=\frac { A_{ s }{ f }_{ y } }{ 0.85f_{ c }^{ ' }b } 5.720 in Not really necessary if tension governs but it is useful later if you want to calculate out the actual capacity. I can demonstrate how this works in a future post.
12 c=\frac { a }{ { \beta }_{ 1 } } 6.729 in
13 \phi =MAX\left( \left( 0.23+\frac { 0.25 }{ \frac { c }{ d } } \right) ,0.65 \right) Not applicable since tension governs.
14 { A }_{ s.req(c) }={ A }_{ s.req }\left( \frac { 0.9 }{ \phi } \right) Not applicable since tension governs.

And done!

Now if you change Mu to 300 kip-ft, you can see how it works if compression governs (I won't demonstrate here).

Final Thoughts

Of course, as I mentioned earlier, just like any other engineering topics, this is not the only way to design a rectangular concrete beam but it's a fairly straightforward way to do it.

Note that I didn't cover shear design as it will come in a later post.

Is this helpful? Let me know what you think in the comments below!

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