緊張で硬化コンクリートの試験

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Structural Engineering
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JoVE Science Education Structural Engineering
Tests of Hardened Concrete in Tension

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10:09 min

April 30, 2023

Overview

Source: Roberto Leon, Department of Civil and Environmental Engineering, Virginia Tech, Blacksburg, VA

In a previous laboratory focused on concrete in compression, we observed that concrete can withstand very large stresses under uniaxial compressive forces. However, the failures observed were not compressive failures but failures along shear planes where maximum tensile forces occur. Thus, it is important to understand the behavior of concrete in tension and particularly its maximum strength as that will govern both its ultimate and service behavior. From the ultimate standpoint, combinations of tension and shear stresses will lead to cracking and immediate and catastrophic failure. For that reason, concrete is seldom if ever used in an unreinforced condition in structural applications; most concrete members will be reinforced with steel so that these cracks can be stopped and the crack widths limited. The latter is important from the serviceability standpoint because controlling crack widths and distribution is the key to durability, as this will impede deicing salts and similar chemicals from penetrating and corroding the reinforcing steel.

The objectives of this experiment are threefold: (1) to conduct tensile split cylinder tests to determine concrete tensile strength, (2) to conduct beam tests to determine concrete tensile strength, and (3) to demonstrate the influence of steel reinforcement on behavior by comparing the behavior of lightly reinforced beam with an unreinforced one.

Principles

The tensile capacity (ft) of a brittle composite material like concrete is often in the range of 1/10 of its compression capacity (f’c). This behavior is driven by the existence of a very weak layer, called the interfacial transition zone (ITZ), between the mortar and the aggregate. This very thin layer (only about 40 μm or so) contains less unhydrated cement and calcium silicates hydrates (C-S-H) than the mortar, but more large oriented crystals of calcium hydroxide (C-H) as well as trisulfate hydrates (or ettringite, the long needle-like structures). Both of these factors contribute to a larger porosity in this layer and thus to a lower strength. In addition, the fact that the average spacing between aggregate particles is only 2 to 2.5 times the thickness of the ITZ, means that a very significant amount of the mortar, by some estimates up to 40%, is made up of this weaker material. 

The brittle behavior of concrete is driven by the growth of microcracks that propagate from stress concentrations that occur between the aggregate and mortar. What is, conceptually, the state of stress around an idealized round aggregate particle as a compressive load is applied? As the compression tries to “flow” around the particle and the force vector becomes inclined, tensile forces develop in the horizontal direction. These forces are higher at the interface due to stress concentrations. The combination of large tensile forces and a weak ITZ lead to preferential cracking in this area. 

As the compressive stress increases in a cylinder test, these cracks begin to grow and propagate as the result of the transverse tensile stresses, existing initial microcracks and the presence of the weak ITZ. The crack growth will become unstable as the concrete reaches its maximum strength, and the concrete will loose its ability to maintain strength very rapidly as cracks propagate at great speed. This results in overall brittle behavior for concrete, as well as for many similar ceramic materials with weak interface zones.

The characteristic low tensile capacity of concrete also makes a direct tension test very difficult to conduct, as conventional tensile specimens tend to fail at the grips due to stress concentrations. An elegant solution around this problem is to test cylinders on their side. This method is called the split cylinder, or Brazilian test. In this test, as one moves away from the loading heads, where there is a complex state of stress, a uniform horizontal tensile stress field will develop. Since the concrete is weak in tension, this will lead to a vertical crack and the splitting of the cylinder. From statistical studies, the split cylinder test is expected to give tensile capacities on the order of 6√f'c

Another indirect way of testing concrete in tension is to use a short beam specimen in a four-point bending test configuration. The central portion of the beam is under constant moment and zero shear, and thus a simple relationship can be derived between the failure load, the geometric properties and the tensile strength of the beam using elastic theory principles. The beam will fail suddenly as soon as a crack forms at the bottom and have no residual strength. Although it is well known that at failure the distribution of strains across the depth of the concrete beam does not quite follow those of the elastic theory, this inconsistency is generally considered to have little influence on the final results. From statistical studies, the beam tensile test is expected to give tensile capacities on the order of 7.5√f'c

The sudden and brittle failure observed in the concrete beam test would be unacceptable in any practical application, where ductility and residual strength to carry at least gravity loads is needed. Steel reinforcement is added at the bottom (or tensile side) of the beam to prevent such sudden failures; as the concrete begins to crack, the steel will begin to take up the tensile forces. The technique works as long as the bars, which have surface deformations to help them transfer forces from the concrete, are properly anchored. In the case of a short beam like the one that will be tested here, this will be accomplished by providing a hook at the end of the bars. In addition, because diagonal shear cracks can occur near the mid depth of the beam, vertical stirrups are generally provided. Finally, because of the indeterminate nature of reinforced concrete structures, it is hard to know for sure where tension and compression will be on a beam under a particular set of loads. For that reason, bars will also be placed at the top, resulting in the typical steel cage that is seen in most beams in reinforced concrete structures. 

Procedure

1. Split Tension Test

  1. For this test, use the sample cylinders that were previously prepared (see JoVE video Tests on fresh concrete). Obtain two thin strips of balsa wood or similar (about 1/8 thick x 1 wide x 8 long) to help distribute the loads on the cylinders.
  2. Measure the dimensions of the two cylinders. Draw a line along the diameter on each end of the specimen bisecting the cylinder.
  3. Center one strip along the center of the lower bearing block of the testing machine.
  4. Place the cylinder on the strip and align so that the lines marked on the ends of the specimen are vertical and centered over the strip.
  5. Place a second strip lengthwise on the cylinder.
  6. Lower the upper loading head of the testing machine until the assembly is secured in the machine.
  7. Estimate the maximum loading the specimen can take assuming the tensile strength is 6f'c , where f'is the nominal concrete compressive strength.
  8. Apply the compressive load slowly (at around 100 psi to 200 psi per min.) and continuously until the specimen fails in split tension.
  9. Record the maximum applied load.
  10. Examine the fracture surface and estimate the percentage of aggregate that has fractured.

2. Beam Tension Test

  1. Construct one concrete beam with a 4 in. x 4 in. cross section and 36 in. in length.
  2. Install a 4-point bending test apparatus in the testing machine.
  3. Carefully lift the beam and install it into the test set up.
  4. Turn on the testing machine and activate the software to read load and deformations.
  5. Estimate the maximum loading the specimen can take assuming the tensile strength is 7.5f'c and apply the compressive load slowly (at around 100 psi to 200 psi per min.) and continuously until the specimen fails.
  6. Record the maximum applied load. 
  7. Examine the fracture surface and estimate the percentage of aggregate that has fractured.

3. Reinforced Beam Test

  1. Construct one concrete beam, reinforced with two #3 bars (3/8 in. diameter) located about 0.5 in. from the bottom. The bars have hooks at the ends to prevent a bar pullout failure. The beam is 4-inch x 4-inch in cross-section with a 36 inches in unsupported length.
  2. Install a 4-point bending test apparatus in the testing machine.
  3. Carefully lift the beam and install it into the test set up.
  4. Turn on the testing machine and activate the software to read load and deformations.
  5. Estimate the maximum loading the specimen can take assuming the tensile strength is 7.5f'c and apply the compressive load slowly (at around 100 psi to 200 psi per min.) and continuously until the specimen fails.
  6. Record the applied load and deformations as the test progresses.

Reinforced concrete has greater strength than unreinforced concrete because the steel in the reinforced section can be used to carry large tensile forces, as will be demonstrated in this laboratory testing.

Concrete can withstand very large stresses under uniaxial compressive forces. However, the failures observed are not compressive in nature but failures along shear planes where maximum tensile forces occur. This sudden type of failure is unacceptable in structural applications and most concrete is reinforced with steel to increase its strength and ductility.

In practical applications, bars are added in a steel cage pattern to cross potential planes of tensile failure. Steel reinforcement serves to limit crack formation and crack widths, increasing the life of the structure. De-icing salts and other chemicals are impeded from penetrating and corroding the reinforcing steel. Stiffness of the structural members is maintained and long-term deflections are reduced, and the aesthetic appearance of concrete structures is improved.

In this video, we will conduct tests to determine concrete tensile strength and compare reinforced with unreinforced concrete.

In concrete, a very thin, weak layer between the mortar and the aggregate, called the interfacial transition zone, results in very low tensile strengths. Because the design of common concretes is driven by the need to maximize the aggregate content and minimize the mortar volume, the particle spacing is very small, with up to 40% of the mortar volume made up of the weaker ITZ material. The local, larger, water to cement ratio during mixing and hardening in the interphase area, results in weaker crystal structure in the ITZ. This condition, coupled with the stress concentrations around the irregular aggregate particles, leads to preferential crack growth in this area.

To test the tensile properties of concrete, a method known as the split cylinder test is often used. A compressive force is applied resulting in a uniform, horizontal tensile stress, in locations away from the applied load.

A correlation is typically seen between the tensile and compressive strengths, although typical coefficients of variation for these relationships are high. Another method used is a four-point bending test configuration. In this test, the top fiber is in compression and the bottom one, in tension. When the tensile strength is reached at the bottom, a crack forms causing immediate failure.

A similar correlation of tensile and compressive strengths is seen for this test. The beam test results in predictions of tensile capacity, generally 30 to 50% larger than the split tension test. But because cracking in many concrete elements is due to flexure, the values from the beam tests are typically used in design. To compare unreinforced to reinforced concrete, steel bars are placed in the bottom tensile side of a beam and then tested.

In the next section, we will measure the tensile strength of unreinforced concrete using the split tension test and compare the tensile strength of unreinforced and reinforced concrete, using the beam tension test.

For these tests, use the sample cylinders that were prepared in our video discussing fresh concrete. Use a thin strip of balsa wood and a stiff steel bar to help distribute the loads uniformly from the cylindrical loading heads in the compression testing machine. Draw a line along the diameter on each end of the specimen, bisecting the cylinder. Next, center one wooden strip and stiff steel bar along the center of the lower bearing block of the testing machine.

Now, place the cylinder on the strip and align so that the lines marked on the ends of the specimen are vertical and centered over the strip. Next, place the second wooden strip and steel bar lengthwise on top of the cylinder. Then, lower the upper loading head of the testing machine until the assembly is secured in the machine.

Apply the compressive load slowly and continuously until the specimen fails in split tension. Finally, record the maximum applied load. Examine the fracture surface and estimate the percentage of aggregate that has fractured. Repeat this process for the second cylinder to get an idea of the variation.

Construct two concrete beams, one without reinforcement, and one reinforced with 2 number three bars located about 0.5 inches from the bottom. The bars have hooks at the ends to prevent a bar-pullout failure. Both beams are 4 inch by 4 inch in cross-section with 16 inches in unsupported length.

Carefully lift the concrete beam and install it into the setup. Then install a four-point bending test apparatus in the testing machine as shown. The test is called a four-point bending test because we have two supports at the ends and two load points at the third point.

Turn on the testing machine and activate the software to read load and deformations. Next, apply the compressive load slowly and continuously until the specimen fails. Record the maximum applied load. Finally, examine the fracture surface and estimate the percentage of aggregate that has fractured.

Repeat the same protocol for the reinforced concrete beam. In this case, steel reinforcement at the bottom or tensile side of the beam, prevents sudden brittle failures. As the concrete begins to crack, the steel will begin to take up the tensile forces. This technique works as long as the steel bars, which have surface deformations to help them transfer forces from the concrete, are properly anchored.

Calculate the tensile strength for the maximum compressive load reached during the split tensile test. For these tests, the average was 388 psi with a standard deviation of 22.2 psi.

Calculate the tensile strength for the maximum compressive load reached during the beam tensile test. For these tests, the average was 522.9 psi. We can compare the unreinforced and reinforced concrete beams by looking at their load deflection curves.

Initially, both beams followed a similar path with slight differences in initial stiffness, probably due to changes in support conditions. The unreinforced beam failed as soon as initial cracking occurred at a load of about 450 pounds, a load close to the predicted tensile strength. The reinforced beam cracked at a higher load but regained its strength quickly, albeit at a lower overall stiffness. The load continues to increase until the steel begins to yield after which, the curve begins to flatten. Because steel is very ductile and strain hardens, failure occurs at large deformations.

A comparison of the two curves shows the dramatic difference in performance. The difference in strength is very large but it should be noted that this is related to the area of steel used.

Now that you appreciate the need for steel reinforcement in concrete, let’s look at a couple of common applications. Using just one to 1 to 1.5% steel over the area of the concrete cross section can make concrete structures that are economical, safe and provide good serviceability. Many football stadiums, such as Soldier Field in Chicago, owe their unique forms to reinforced concrete.

Frank Lloyd Wright brought reinforced concrete into the world of modern-day architecture. Making use of its ability to maintain its integrity in unsupported cantilevers, Wright used the material in some of his greatest works, including Fallingwater in Pennsylvania.

You’ve just watched JoVE’s introduction to compression tests on hardened concrete in tension. You should now understand the brittle nature of tensile failures in concrete and know the standard laboratory tests for determining the strength of unreinforced and reinforced concrete under tension.

Thanks for watching!

Results

The tensile strength for the maximum compressive load reached during the split tensile test is given by the following formula: 
ft = 2Pmax/ (πDL)
where D is the diameter (inches), L is the length (inches), and Pmax is the maximum compressive load (lb.) reached during the tensile test. For these tests, the average was 388 psi with a standard deviation of 22.2 psi (Table 1).

Test # Equation 1(psi) P (lbs) Equation 2(psi) Equation 3
1 4780 18456 367.17 5.31
2 4780 20678 411.38 5.95
3 4780 19385 385.65 5.58
Average = 388.07 5.61
St. Dev. 22.20 0.32

Table 1. Results for the split tensile test.

The tensile strength for the maximum compressive load reached during the beam tensile test is given by the following formula:
ft = PmaxL/ (bd2)
where d is the depth (inches), b is the width, L is the length (inches), and Pmax is the maximum compressive load (lb.) reached during the tensile test. This formula is valid for the case where the loads are applied at the third points. For these tests, the average was 522.9 psi (Table 2).

Test # Equation 1(psi) P (lbs) Equation 2(psi) Equation 3
1 4780 2675 501.6 7.3
2 4780 2903 544.3 7.9
Average = 522.9 7.6
St. Dev. 30.23 0.44

Table 2. Results for the beam tensile test.

The load-deflection curve for the unreinforced and reinforced concrete beams is shown in Fig. 1. The unreinforced beam likely followed the same load path initially, but failed as soon as the initial cracking occurred. The reinforced one shows a slight discontinuity when the initial cracking occurred and a slightly lower stiffness as it begins to pick up load again in its cracked condition. The load continuous to increase until the concrete begins to yield, when the curve begins to flatten. However, because the steel is very ductile and strain-hardens, the load will continue to increase slightly and failure will occur at very large deformations when the concrete on top crushes.

Figure 1
Figure 1: Comparison of load-deflection curves for unreinforced (blue) and reinforced (red) concrete beams at (a) small loads and (b) large loads (full curves). 

Applications and Summary

The test demonstrated the brittle nature of tensile failures in concrete and showed that the tensile strength is only a fraction (1/8 to 1/12) that of the compressive strength. Brittle failures of this type could have catastrophic consequences for human safety, and thus all concrete structures need to be reinforced with steel (or similar) bars to take tensile forces. A comparison of the load-deformation curve for the unreinforced and reinforced beams indicate not only that the latter possesses greater strength but also large deformation capacity.

The key to the safety and long-term performance of concrete structures is to provide steel reinforcement in areas of high tensile and shear stresses. In general, the amount of steel necessary to reach this goal is small, on the order of 1%-1.5% of the area of the concrete cross section. This small amount means that concrete structures can be economical, safe and provide good serviceability. In addition, the ability to cast concrete into any desired form gives architect great leeway in developing aesthetically pleasing structures.

Transcript

Reinforced concrete has greater strength than unreinforced concrete because the steel in the reinforced section can be used to carry large tensile forces, as will be demonstrated in this laboratory testing.

Concrete can withstand very large stresses under uniaxial compressive forces. However, the failures observed are not compressive in nature but failures along shear planes where maximum tensile forces occur. This sudden type of failure is unacceptable in structural applications and most concrete is reinforced with steel to increase its strength and ductility.

In practical applications, bars are added in a steel cage pattern to cross potential planes of tensile failure. Steel reinforcement serves to limit crack formation and crack widths, increasing the life of the structure. De-icing salts and other chemicals are impeded from penetrating and corroding the reinforcing steel. Stiffness of the structural members is maintained and long-term deflections are reduced, and the aesthetic appearance of concrete structures is improved.

In this video, we will conduct tests to determine concrete tensile strength and compare reinforced with unreinforced concrete.

In concrete, a very thin, weak layer between the mortar and the aggregate, called the interfacial transition zone, results in very low tensile strengths. Because the design of common concretes is driven by the need to maximize the aggregate content and minimize the mortar volume, the particle spacing is very small, with up to 40% of the mortar volume made up of the weaker ITZ material. The local, larger, water to cement ratio during mixing and hardening in the interphase area, results in weaker crystal structure in the ITZ. This condition, coupled with the stress concentrations around the irregular aggregate particles, leads to preferential crack growth in this area.

To test the tensile properties of concrete, a method known as the split cylinder test is often used. A compressive force is applied resulting in a uniform, horizontal tensile stress, in locations away from the applied load.

A correlation is typically seen between the tensile and compressive strengths, although typical coefficients of variation for these relationships are high. Another method used is a four-point bending test configuration. In this test, the top fiber is in compression and the bottom one, in tension. When the tensile strength is reached at the bottom, a crack forms causing immediate failure.

A similar correlation of tensile and compressive strengths is seen for this test. The beam test results in predictions of tensile capacity, generally 30 to 50% larger than the split tension test. But because cracking in many concrete elements is due to flexure, the values from the beam tests are typically used in design. To compare unreinforced to reinforced concrete, steel bars are placed in the bottom tensile side of a beam and then tested.

In the next section, we will measure the tensile strength of unreinforced concrete using the split tension test and compare the tensile strength of unreinforced and reinforced concrete, using the beam tension test.

For these tests, use the sample cylinders that were prepared in our video discussing fresh concrete. Use a thin strip of balsa wood and a stiff steel bar to help distribute the loads uniformly from the cylindrical loading heads in the compression testing machine. Draw a line along the diameter on each end of the specimen, bisecting the cylinder. Next, center one wooden strip and stiff steel bar along the center of the lower bearing block of the testing machine.

Now, place the cylinder on the strip and align so that the lines marked on the ends of the specimen are vertical and centered over the strip. Next, place the second wooden strip and steel bar lengthwise on top of the cylinder. Then, lower the upper loading head of the testing machine until the assembly is secured in the machine.

Apply the compressive load slowly and continuously until the specimen fails in split tension. Finally, record the maximum applied load. Examine the fracture surface and estimate the percentage of aggregate that has fractured. Repeat this process for the second cylinder to get an idea of the variation.

Construct two concrete beams, one without reinforcement, and one reinforced with 2 number three bars located about 0.5 inches from the bottom. The bars have hooks at the ends to prevent a bar-pullout failure. Both beams are 4 inch by 4 inch in cross-section with 16 inches in unsupported length.

Carefully lift the concrete beam and install it into the setup. Then install a four-point bending test apparatus in the testing machine as shown. The test is called a four-point bending test because we have two supports at the ends and two load points at the third point.

Turn on the testing machine and activate the software to read load and deformations. Next, apply the compressive load slowly and continuously until the specimen fails. Record the maximum applied load. Finally, examine the fracture surface and estimate the percentage of aggregate that has fractured.

Repeat the same protocol for the reinforced concrete beam. In this case, steel reinforcement at the bottom or tensile side of the beam, prevents sudden brittle failures. As the concrete begins to crack, the steel will begin to take up the tensile forces. This technique works as long as the steel bars, which have surface deformations to help them transfer forces from the concrete, are properly anchored.

Calculate the tensile strength for the maximum compressive load reached during the split tensile test. For these tests, the average was 388 psi with a standard deviation of 22.2 psi.

Calculate the tensile strength for the maximum compressive load reached during the beam tensile test. For these tests, the average was 522.9 psi. We can compare the unreinforced and reinforced concrete beams by looking at their load deflection curves.

Initially, both beams followed a similar path with slight differences in initial stiffness, probably due to changes in support conditions. The unreinforced beam failed as soon as initial cracking occurred at a load of about 450 pounds, a load close to the predicted tensile strength. The reinforced beam cracked at a higher load but regained its strength quickly, albeit at a lower overall stiffness. The load continues to increase until the steel begins to yield after which, the curve begins to flatten. Because steel is very ductile and strain hardens, failure occurs at large deformations.

A comparison of the two curves shows the dramatic difference in performance. The difference in strength is very large but it should be noted that this is related to the area of steel used.

Now that you appreciate the need for steel reinforcement in concrete, let’s look at a couple of common applications. Using just one to 1 to 1.5% steel over the area of the concrete cross section can make concrete structures that are economical, safe and provide good serviceability. Many football stadiums, such as Soldier Field in Chicago, owe their unique forms to reinforced concrete.

Frank Lloyd Wright brought reinforced concrete into the world of modern-day architecture. Making use of its ability to maintain its integrity in unsupported cantilevers, Wright used the material in some of his greatest works, including Fallingwater in Pennsylvania.

You’ve just watched JoVE’s introduction to compression tests on hardened concrete in tension. You should now understand the brittle nature of tensile failures in concrete and know the standard laboratory tests for determining the strength of unreinforced and reinforced concrete under tension.

Thanks for watching!